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premiere-libtorrent/src/torrent.cpp

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/*
Copyright (c) 2003, Arvid Norberg
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in
the documentation and/or other materials provided with the distribution.
* Neither the name of the author nor the names of its
contributors may be used to endorse or promote products derived
from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
*/
#include "libtorrent/pch.hpp"
#include <ctime>
#include <algorithm>
#include <set>
#include <cctype>
#include <numeric>
#ifdef TORRENT_DEBUG
#include <iostream>
#endif
#ifdef _MSC_VER
#pragma warning(push, 1)
#endif
#include <boost/bind.hpp>
#ifdef _MSC_VER
#pragma warning(pop)
#endif
#include "libtorrent/config.hpp"
#include "libtorrent/torrent_handle.hpp"
#include "libtorrent/session.hpp"
#include "libtorrent/torrent_info.hpp"
#include "libtorrent/tracker_manager.hpp"
#include "libtorrent/parse_url.hpp"
#include "libtorrent/bencode.hpp"
#include "libtorrent/hasher.hpp"
#include "libtorrent/entry.hpp"
#include "libtorrent/peer.hpp"
#include "libtorrent/peer_connection.hpp"
#include "libtorrent/bt_peer_connection.hpp"
#include "libtorrent/web_peer_connection.hpp"
#include "libtorrent/http_seed_connection.hpp"
#include "libtorrent/peer_id.hpp"
#include "libtorrent/alert.hpp"
#include "libtorrent/identify_client.hpp"
#include "libtorrent/alert_types.hpp"
#include "libtorrent/extensions.hpp"
#include "libtorrent/aux_/session_impl.hpp"
#include "libtorrent/instantiate_connection.hpp"
#include "libtorrent/assert.hpp"
#include "libtorrent/broadcast_socket.hpp"
#include "libtorrent/kademlia/dht_tracker.hpp"
#include "libtorrent/peer_info.hpp"
#if TORRENT_USE_IOSTREAM
#include <iostream>
#endif
using namespace libtorrent;
using boost::tuples::tuple;
using boost::tuples::get;
using boost::tuples::make_tuple;
using boost::bind;
using libtorrent::aux::session_impl;
namespace
{
size_type collect_free_download(
torrent::peer_iterator start
, torrent::peer_iterator end)
{
size_type accumulator = 0;
for (torrent::peer_iterator i = start; i != end; ++i)
{
// if the peer is interested in us, it means it may
// want to trade it's surplus uploads for downloads itself
// (and we should not consider it free). If the share diff is
// negative, there's no free download to get from this peer.
size_type diff = (*i)->share_diff();
TORRENT_ASSERT(diff < (std::numeric_limits<size_type>::max)());
if ((*i)->is_peer_interested() || diff <= 0)
continue;
TORRENT_ASSERT(diff > 0);
(*i)->add_free_upload(-diff);
accumulator += diff;
TORRENT_ASSERT(accumulator > 0);
}
TORRENT_ASSERT(accumulator >= 0);
return accumulator;
}
// returns the amount of free upload left after
// it has been distributed to the peers
size_type distribute_free_upload(
torrent::peer_iterator start
, torrent::peer_iterator end
, size_type free_upload)
{
if (free_upload <= 0) return free_upload;
int num_peers = 0;
size_type total_diff = 0;
for (torrent::peer_iterator i = start; i != end; ++i)
{
size_type d = (*i)->share_diff();
TORRENT_ASSERT(d < (std::numeric_limits<size_type>::max)());
total_diff += d;
if (!(*i)->is_peer_interested() || (*i)->share_diff() >= 0) continue;
++num_peers;
}
if (num_peers == 0) return free_upload;
size_type upload_share;
if (total_diff >= 0)
{
upload_share = (std::min)(free_upload, total_diff) / num_peers;
}
else
{
upload_share = (free_upload + total_diff) / num_peers;
}
if (upload_share < 0) return free_upload;
for (torrent::peer_iterator i = start; i != end; ++i)
{
peer_connection* p = *i;
if (!p->is_peer_interested() || p->share_diff() >= 0) continue;
p->add_free_upload(upload_share);
free_upload -= upload_share;
}
return free_upload;
}
struct find_peer_by_ip
{
find_peer_by_ip(tcp::endpoint const& a, const torrent* t)
: ip(a)
, tor(t)
{ TORRENT_ASSERT(t != 0); }
bool operator()(session_impl::connection_map::value_type const& c) const
{
tcp::endpoint const& sender = c->remote();
if (sender.address() != ip.address()) return false;
if (tor != c->associated_torrent().lock().get()) return false;
return true;
}
tcp::endpoint const& ip;
torrent const* tor;
};
struct peer_by_id
{
peer_by_id(const peer_id& i): pid(i) {}
bool operator()(session_impl::connection_map::value_type const& p) const
{
if (p->pid() != pid) return false;
// have a special case for all zeros. We can have any number
// of peers with that pid, since it's used to indicate no pid.
if (pid.is_all_zeros()) return false;
return true;
}
peer_id const& pid;
};
}
namespace libtorrent
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
#define PRINT_SIZEOF(x) l << "sizeof(" #x "): " << sizeof(x) << "\n";
#define PRINT_OFFSETOF(x, y) l << " " << (offsetof(x, y) - temp) << " offsetof(" #x "," #y "): " << offsetof(x, y) << "\n"; temp = offsetof(x, y);
void torrent::print_size(logger& l)
{
int temp = 0;
PRINT_SIZEOF(torrent)
PRINT_OFFSETOF(torrent, m_policy)
PRINT_OFFSETOF(torrent, m_total_uploaded)
PRINT_OFFSETOF(torrent, m_total_downloaded)
PRINT_OFFSETOF(torrent, m_started)
PRINT_OFFSETOF(torrent, m_torrent_file)
PRINT_OFFSETOF(torrent, m_owning_storage)
PRINT_OFFSETOF(torrent, m_storage)
PRINT_OFFSETOF(torrent, m_connections)
PRINT_OFFSETOF(torrent, m_web_seeds)
PRINT_OFFSETOF(torrent, m_extensions)
PRINT_OFFSETOF(torrent, m_tracker_timer)
PRINT_OFFSETOF(torrent, m_stat)
PRINT_OFFSETOF(torrent, m_ses)
PRINT_OFFSETOF(torrent, m_file_priority)
PRINT_OFFSETOF(torrent, m_file_progress)
PRINT_OFFSETOF(torrent, m_picker)
PRINT_OFFSETOF(torrent, m_trackers)
PRINT_OFFSETOF(torrent, m_time_critical_pieces)
PRINT_OFFSETOF(torrent, m_username)
PRINT_OFFSETOF(torrent, m_password)
PRINT_OFFSETOF(torrent, m_net_interface)
PRINT_OFFSETOF(torrent, m_save_path)
PRINT_OFFSETOF(torrent, m_verified)
PRINT_OFFSETOF(torrent, m_error)
PRINT_OFFSETOF(torrent, m_error_file)
PRINT_OFFSETOF(torrent, m_resume_data)
PRINT_OFFSETOF(torrent, m_resume_entry)
PRINT_OFFSETOF(torrent, m_name)
PRINT_OFFSETOF(torrent, m_storage_constructor)
PRINT_OFFSETOF(torrent, m_obfuscated_hash)
PRINT_OFFSETOF(torrent, m_ratio)
PRINT_OFFSETOF(torrent, m_available_free_upload)
PRINT_OFFSETOF(torrent, m_average_piece_time)
PRINT_OFFSETOF(torrent, m_piece_time_deviation)
PRINT_OFFSETOF(torrent, m_total_failed_bytes)
PRINT_OFFSETOF(torrent, m_total_redundant_bytes)
// PRINT_OFFSETOF(torrent, m_upload_mode_time:24)
// PRINT_OFFSETOF(torrent, m_state:3)
// PRINT_OFFSETOF(torrent, m_storage_mode:2)
// PRINT_OFFSETOF(torrent, m_announcing:1)
// PRINT_OFFSETOF(torrent, m_waiting_tracker:1)
// PRINT_OFFSETOF(torrent, m_seed_mode:1)
// PRINT_OFFSETOF(torrent, m_active_time:24)
PRINT_OFFSETOF(torrent, m_last_working_tracker)
// PRINT_OFFSETOF(torrent, m_finished_time:24)
// PRINT_OFFSETOF(torrent, m_sequential_download:1)
// PRINT_OFFSETOF(torrent, m_got_tracker_response:1)
// PRINT_OFFSETOF(torrent, m_connections_initialized:1)
// PRINT_OFFSETOF(torrent, m_super_seeding:1)
// PRINT_OFFSETOF(torrent, m_override_resume_data:1)
// PRINT_OFFSETOF(torrent, m_resolving_country:1)
// PRINT_OFFSETOF(torrent, m_resolve_countries:1)
// PRINT_OFFSETOF(torrent, m_dummy_padding_bit_to_align:1)
// PRINT_OFFSETOF(torrent, m_seeding_time:24)
PRINT_OFFSETOF(torrent, m_time_scaler)
// PRINT_OFFSETOF(torrent, m_max_uploads:24)
PRINT_OFFSETOF(torrent, m_deficit_counter)
// PRINT_OFFSETOF(torrent, m_num_uploads:24)
// PRINT_OFFSETOF(torrent, m_block_size_shift:5)
// PRINT_OFFSETOF(torrent, m_has_incoming:1)
// PRINT_OFFSETOF(torrent, m_files_checked:1)
// PRINT_OFFSETOF(torrent, m_queued_for_checking:1)
// PRINT_OFFSETOF(torrent, m_max_connections:24)
// PRINT_OFFSETOF(torrent, m_padding:24)
PRINT_OFFSETOF(torrent, m_sequence_number)
// PRINT_OFFSETOF(torrent, m_complete:24)
PRINT_OFFSETOF(torrent, m_priority)
// PRINT_OFFSETOF(torrent, m_incomplete:24)
// PRINT_OFFSETOF(torrent, m_progress_ppm:20)
// PRINT_OFFSETOF(torrent, m_abort:1)
// PRINT_OFFSETOF(torrent, m_paused:1)
// PRINT_OFFSETOF(torrent, m_upload_mode:1)
// PRINT_OFFSETOF(torrent, m_auto_managed:1)
PRINT_OFFSETOF(torrent, m_num_verified)
PRINT_OFFSETOF(torrent, m_last_scrape)
}
#undef PRINT_SIZEOF
#undef PRINT_OFFSETOF
#endif
int root2(int x)
{
int ret = 0;
x >>= 1;
while (x > 0)
{
// if this assert triggers, the block size
// is not an even 2 exponent!
TORRENT_ASSERT(x == 1 || (x & 1) == 0);
++ret;
x >>= 1;
}
return ret;
}
torrent::torrent(
session_impl& ses
, tcp::endpoint const& net_interface
, int block_size
, int seq
, add_torrent_params const& p)
: m_policy(this)
, m_total_uploaded(0)
, m_total_downloaded(0)
, m_started(time_now())
, m_torrent_file(p.ti ? p.ti : new torrent_info(p.info_hash))
, m_storage(0)
, m_tracker_timer(ses.m_io_service)
, m_ses(ses)
, m_trackers(m_torrent_file->trackers())
, m_net_interface(tcp::endpoint(net_interface.address(), 0))
, m_save_path(complete(p.save_path))
, m_storage_constructor(p.storage)
, m_ratio(0.f)
, m_available_free_upload(0)
, m_average_piece_time(0)
, m_piece_time_deviation(0)
, m_total_failed_bytes(0)
, m_total_redundant_bytes(0)
, m_upload_mode_time(0)
, m_state(torrent_status::checking_resume_data)
, m_storage_mode(p.storage_mode)
, m_announcing(false)
, m_waiting_tracker(false)
, m_seed_mode(p.seed_mode && m_torrent_file->is_valid())
, m_active_time(0)
, m_last_working_tracker(-1)
, m_finished_time(0)
, m_sequential_download(false)
, m_got_tracker_response(false)
, m_connections_initialized(p.ti)
, m_super_seeding(false)
, m_override_resume_data(p.override_resume_data)
#ifndef TORRENT_DISABLE_RESOLVE_COUNTRIES
, m_resolving_country(false)
, m_resolve_countries(false)
#endif
, m_seeding_time(0)
, m_time_scaler(0)
, m_max_uploads(~0)
, m_deficit_counter(0)
, m_num_uploads(0)
, m_block_size_shift(root2(p.ti ? (std::min)(block_size, m_torrent_file->piece_length()) : block_size))
, m_has_incoming(false)
, m_files_checked(false)
, m_queued_for_checking(false)
, m_max_connections(~0)
, m_padding(0)
, m_sequence_number(seq)
, m_complete(~1)
, m_priority(0)
, m_incomplete(~1)
, m_progress_ppm(0)
, m_abort(false)
, m_paused(p.paused)
, m_upload_mode(p.upload_mode)
, m_auto_managed(p.auto_managed)
, m_num_verified(0)
, m_last_scrape(0)
{
if (m_seed_mode)
m_verified.resize(m_torrent_file->num_pieces(), false);
if (p.resume_data) m_resume_data.swap(*p.resume_data);
if (settings().prefer_udp_trackers)
prioritize_udp_trackers();
#ifndef TORRENT_DISABLE_ENCRYPTION
hasher h;
h.update("req2", 4);
h.update((char*)&m_torrent_file->info_hash()[0], 20);
m_obfuscated_hash = h.final();
#endif
#ifdef TORRENT_DEBUG
m_files_checked = false;
#endif
INVARIANT_CHECK;
if (p.name && !p.ti) m_name.reset(new std::string(p.name));
if (p.tracker_url && std::strlen(p.tracker_url) > 0)
{
m_trackers.push_back(announce_entry(p.tracker_url));
m_trackers.back().fail_limit = 0;
m_trackers.back().source = announce_entry::source_magnet_link;
m_torrent_file->add_tracker(p.tracker_url);
}
}
void torrent::start()
{
TORRENT_ASSERT(!m_picker);
if (!m_seed_mode)
{
m_picker.reset(new piece_picker());
std::fill(m_file_progress.begin(), m_file_progress.end(), 0);
if (!m_resume_data.empty())
{
if (lazy_bdecode(&m_resume_data[0], &m_resume_data[0]
+ m_resume_data.size(), m_resume_entry) != 0)
{
std::vector<char>().swap(m_resume_data);
if (m_ses.m_alerts.should_post<fastresume_rejected_alert>())
{
error_code ec(errors::parse_failed);
m_ses.m_alerts.post_alert(fastresume_rejected_alert(get_handle(), ec));
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << "fastresume data for "
<< torrent_file().name() << " rejected: " << ec.message() << "\n";
#endif
}
}
}
}
// we need to start announcing since we don't have any
// metadata. To receive peers to ask for it.
if (m_torrent_file->is_valid())
{
init();
}
else
{
set_state(torrent_status::downloading_metadata);
if (!m_trackers.empty()) start_announcing();
}
}
#ifndef TORRENT_DISABLE_DHT
bool torrent::should_announce_dht() const
{
if (m_ses.m_listen_sockets.empty()) return false;
if (!m_ses.m_dht) return false;
if (m_torrent_file->is_valid() && !m_files_checked) return false;
// don't announce private torrents
if (m_torrent_file->is_valid() && m_torrent_file->priv()) return false;
if (m_trackers.empty()) return true;
if (!settings().use_dht_as_fallback) return true;
int verified_trackers = 0;
for (std::vector<announce_entry>::const_iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
if (i->verified) ++verified_trackers;
return verified_trackers == 0;
}
#endif
torrent::~torrent()
{
// The invariant can't be maintained here, since the torrent
// is being destructed, all weak references to it have been
// reset, which means that all its peers already have an
// invalidated torrent pointer (so it cannot be verified to be correct)
// i.e. the invariant can only be maintained if all connections have
// been closed by the time the torrent is destructed. And they are
// supposed to be closed. So we can still do the invariant check.
TORRENT_ASSERT(m_connections.empty());
INVARIANT_CHECK;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
(*(*i)->m_logger) << "*** DESTRUCTING TORRENT\n";
}
#endif
TORRENT_ASSERT(m_abort);
if (!m_connections.empty())
disconnect_all(errors::torrent_aborted);
}
void torrent::read_piece(int piece)
{
TORRENT_ASSERT(piece >= 0 && piece < m_torrent_file->num_pieces());
int piece_size = m_torrent_file->piece_size(piece);
int blocks_in_piece = (piece_size + block_size() - 1) / block_size();
read_piece_struct* rp = new read_piece_struct;
rp->piece_data.reset(new (std::nothrow) char[piece_size]);
rp->blocks_left = 0;
rp->fail = false;
peer_request r;
r.piece = piece;
r.start = 0;
for (int i = 0; i < blocks_in_piece; ++i, r.start += block_size())
{
r.length = (std::min)(piece_size - r.start, block_size());
filesystem().async_read(r, bind(&torrent::on_disk_read_complete
, shared_from_this(), _1, _2, r, rp));
++rp->blocks_left;
}
}
void torrent::send_upload_only()
{
#ifndef TORRENT_DISABLE_EXTENSIONS
for (std::set<peer_connection*>::iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
{
if ((*i)->type() != peer_connection::bittorrent_connection) continue;
bt_peer_connection* p = (bt_peer_connection*)*i;
p->write_upload_only();
}
#endif
}
void torrent::set_upload_mode(bool b)
{
if (b == m_upload_mode) return;
m_upload_mode = b;
send_upload_only();
if (m_upload_mode)
{
// clear request queues of all peers
for (std::set<peer_connection*>::iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
{
peer_connection* p = (*i);
p->cancel_all_requests();
}
// this is used to try leaving upload only mode periodically
m_upload_mode_time = 0;
}
else
{
// send_block_requests on all peers
for (std::set<peer_connection*>::iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
{
peer_connection* p = (*i);
p->send_block_requests();
}
}
}
void torrent::handle_disk_error(disk_io_job const& j, peer_connection* c)
{
if (!j.error) return;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << "disk error: '" << j.error.message()
<< " in file " << j.error_file
<< " in torrent " << torrent_file().name()
<< "\n";
#endif
TORRENT_ASSERT(j.piece >= 0);
piece_block block_finished(j.piece, j.offset / block_size());
if (j.action == disk_io_job::write)
{
// we failed to write j.piece to disk tell the piece picker
if (has_picker() && j.piece >= 0) picker().write_failed(block_finished);
}
if (j.error ==
#if BOOST_VERSION == 103500
error_code(boost::system::posix_error::not_enough_memory, get_posix_category())
#elif BOOST_VERSION > 103500
error_code(boost::system::errc::not_enough_memory, get_posix_category())
#else
asio::error::no_memory
#endif
)
{
if (alerts().should_post<file_error_alert>())
alerts().post_alert(file_error_alert(j.error_file, get_handle(), j.error));
if (c) c->disconnect(errors::no_memory);
return;
}
// notify the user of the error
if (alerts().should_post<file_error_alert>())
alerts().post_alert(file_error_alert(j.error_file, get_handle(), j.error));
if (j.action == disk_io_job::write)
{
// if we failed to write, stop downloading and just
// keep seeding.
// TODO: make this depend on the error and on the filesystem the
// files are being downloaded to. If the error is no_space_left_on_device
// and the filesystem doesn't support sparse files, only zero the priorities
// of the pieces that are at the tails of all files, leaving everything
// up to the highest written piece in each file
set_upload_mode(true);
return;
}
// put the torrent in an error-state
set_error(j.error, j.error_file);
pause();
}
void torrent::on_disk_read_complete(int ret, disk_io_job const& j, peer_request r, read_piece_struct* rp)
{
mutex::scoped_lock l(m_ses.m_mutex);
disk_buffer_holder buffer(m_ses, j.buffer);
--rp->blocks_left;
if (ret != r.length)
{
rp->fail = true;
handle_disk_error(j);
}
else
{
std::memcpy(rp->piece_data.get() + r.start, j.buffer, r.length);
}
if (rp->blocks_left == 0)
{
int size = m_torrent_file->piece_size(r.piece);
if (rp->fail)
{
rp->piece_data.reset();
size = 0;
}
if (m_ses.m_alerts.should_post<read_piece_alert>())
{
m_ses.m_alerts.post_alert(read_piece_alert(
get_handle(), r.piece, rp->piece_data, size));
}
delete rp;
}
}
void torrent::add_piece(int piece, char const* data, int flags)
{
TORRENT_ASSERT(piece >= 0 && piece < m_torrent_file->num_pieces());
int piece_size = m_torrent_file->piece_size(piece);
int blocks_in_piece = (piece_size + block_size() - 1) / block_size();
// avoid crash trying to access the picker when there is nont
if (is_seed()) return;
peer_request p;
p.piece = piece;
p.start = 0;
picker().inc_refcount(piece);
for (int i = 0; i < blocks_in_piece; ++i, p.start += block_size())
{
if (picker().is_finished(piece_block(piece, i))
&& (flags & torrent::overwrite_existing) == 0)
continue;
p.length = (std::min)(piece_size - p.start, int(block_size()));
char* buffer = m_ses.allocate_disk_buffer("add piece");
// out of memory
if (buffer == 0)
{
picker().dec_refcount(piece);
return;
}
disk_buffer_holder holder(m_ses, buffer);
std::memcpy(buffer, data + p.start, p.length);
filesystem().async_write(p, holder, bind(&torrent::on_disk_write_complete
, shared_from_this(), _1, _2, p));
piece_block block(piece, i);
picker().mark_as_downloading(block, 0, piece_picker::fast);
picker().mark_as_writing(block, 0);
}
async_verify_piece(piece, bind(&torrent::piece_finished
, shared_from_this(), piece, _1));
picker().dec_refcount(piece);
}
void torrent::on_disk_write_complete(int ret, disk_io_job const& j
, peer_request p)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
if (is_seed()) return;
if (m_abort)
{
piece_block block_finished(p.piece, p.start / block_size());
return;
}
piece_block block_finished(p.piece, p.start / block_size());
if (ret == -1)
{
handle_disk_error(j);
return;
}
// if we already have this block, just ignore it.
// this can happen if the same block is passed in through
// add_piece() multiple times
if (picker().is_finished(block_finished)) return;
picker().mark_as_finished(block_finished, 0);
// did we just finish the piece?
if (picker().is_piece_finished(p.piece))
{
async_verify_piece(p.piece, bind(&torrent::piece_finished, shared_from_this()
, p.piece, _1));
}
}
void torrent::on_disk_cache_complete(int ret, disk_io_job const& j)
{
// suggest this piece to all peers
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
(*i)->send_suggest(j.piece);
}
bool torrent::add_merkle_nodes(std::map<int, sha1_hash> const& nodes, int piece)
{
return m_torrent_file->add_merkle_nodes(nodes, piece);
}
peer_request torrent::to_req(piece_block const& p) const
{
int block_offset = p.block_index * block_size();
int block = (std::min)(torrent_file().piece_size(
p.piece_index) - block_offset, int(block_size()));
TORRENT_ASSERT(block > 0);
TORRENT_ASSERT(block <= block_size());
peer_request r;
r.piece = p.piece_index;
r.start = block_offset;
r.length = block;
return r;
}
std::string torrent::name() const
{
if (valid_metadata()) return m_torrent_file->name();
if (m_name) return *m_name;
return "";
}
#ifndef TORRENT_DISABLE_EXTENSIONS
void torrent::add_extension(boost::shared_ptr<torrent_plugin> ext)
{
m_extensions.push_back(ext);
}
void torrent::add_extension(boost::function<boost::shared_ptr<torrent_plugin>(torrent*, void*)> const& ext
, void* userdata)
{
boost::shared_ptr<torrent_plugin> tp(ext(this, userdata));
if (!tp) return;
add_extension(tp);
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
peer_connection* p = *i;
boost::shared_ptr<peer_plugin> pp(tp->new_connection(p));
if (pp) p->add_extension(pp);
}
// if files are checked for this torrent, call the extension
// to let it initialize itself
if (m_connections_initialized)
tp->on_files_checked();
}
#endif
// this may not be called from a constructor because of the call to
// shared_from_this()
void torrent::init()
{
TORRENT_ASSERT(m_torrent_file->is_valid());
TORRENT_ASSERT(m_torrent_file->num_files() > 0);
TORRENT_ASSERT(m_torrent_file->total_size() >= 0);
m_file_priority.resize(m_torrent_file->num_files(), 1);
m_file_progress.resize(m_torrent_file->num_files(), 0);
m_block_size_shift = root2((std::min)(int(block_size()), m_torrent_file->piece_length()));
if (m_torrent_file->num_pieces() > piece_picker::max_pieces)
{
set_error(errors::too_many_pieces_in_torrent, "");
pause();
return;
}
if (m_torrent_file->num_pieces() == 0)
{
set_error(errors::torrent_invalid_length, "");
pause();
return;
}
// the shared_from_this() will create an intentional
// cycle of ownership, se the hpp file for description.
m_owning_storage = new piece_manager(shared_from_this(), m_torrent_file
, m_save_path, m_ses.m_files, m_ses.m_disk_thread, m_storage_constructor
, (storage_mode_t)m_storage_mode);
m_storage = m_owning_storage.get();
if (has_picker())
{
int blocks_per_piece = (m_torrent_file->piece_length() + block_size() - 1) / block_size();
int blocks_in_last_piece = ((m_torrent_file->total_size() % m_torrent_file->piece_length())
+ block_size() - 1) / block_size();
m_picker->init(blocks_per_piece, blocks_in_last_piece, m_torrent_file->num_pieces());
}
std::vector<std::string> const& url_seeds = m_torrent_file->url_seeds();
for (std::vector<std::string>::const_iterator i = url_seeds.begin()
, end(url_seeds.end()); i != end; ++i)
add_web_seed(*i, web_seed_entry::url_seed);
std::vector<std::string> const& http_seeds = m_torrent_file->http_seeds();
for (std::vector<std::string>::const_iterator i = http_seeds.begin()
, end(http_seeds.end()); i != end; ++i)
add_web_seed(*i, web_seed_entry::http_seed);
if (m_seed_mode)
{
m_ses.m_io_service.post(boost::bind(&torrent::files_checked_lock, shared_from_this()));
std::vector<char>().swap(m_resume_data);
lazy_entry().swap(m_resume_entry);
return;
}
set_state(torrent_status::checking_resume_data);
if (m_resume_entry.type() == lazy_entry::dict_t)
{
int ev = 0;
if (m_resume_entry.dict_find_string_value("file-format") != "libtorrent resume file")
ev = errors::invalid_file_tag;
std::string info_hash = m_resume_entry.dict_find_string_value("info-hash");
if (!ev && info_hash.empty())
ev = errors::missing_info_hash;
if (!ev && sha1_hash(info_hash) != m_torrent_file->info_hash())
ev = errors::mismatching_info_hash;
if (ev && m_ses.m_alerts.should_post<fastresume_rejected_alert>())
{
m_ses.m_alerts.post_alert(fastresume_rejected_alert(get_handle()
, error_code(ev, get_libtorrent_category())));
}
if (ev)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << "fastresume data for "
<< torrent_file().name() << " rejected: "
<< error_code(ev, get_libtorrent_category()).message() << "\n";
#endif
std::vector<char>().swap(m_resume_data);
lazy_entry().swap(m_resume_entry);
}
else
{
read_resume_data(m_resume_entry);
}
}
TORRENT_ASSERT(block_size() > 0);
int file = 0;
for (file_storage::iterator i = m_torrent_file->files().begin()
, end(m_torrent_file->files().end()); i != end; ++i, ++file)
{
if (!i->pad_file) continue;
m_padding += i->size;
peer_request pr = m_torrent_file->map_file(file, 0, m_torrent_file->file_at(file).size);
int off = pr.start & (block_size()-1);
if (off != 0) { pr.length -= block_size() - off; pr.start += block_size() - off; }
TORRENT_ASSERT((pr.start & (block_size()-1)) == 0);
int block = block_size();
int blocks_per_piece = m_torrent_file->piece_length() / block;
piece_block pb(pr.piece, pr.start / block_size());
for (; pr.length >= block; pr.length -= block, ++pb.block_index)
{
if (pb.block_index == blocks_per_piece) { pb.block_index = 0; ++pb.piece_index; }
m_picker->mark_as_finished(pb, 0);
}
}
m_storage->async_check_fastresume(&m_resume_entry
, bind(&torrent::on_resume_data_checked
, shared_from_this(), _1, _2));
}
void torrent::on_resume_data_checked(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
if (ret == piece_manager::fatal_disk_error)
{
handle_disk_error(j);
set_state(torrent_status::queued_for_checking);
std::vector<char>().swap(m_resume_data);
lazy_entry().swap(m_resume_entry);
return;
}
if (m_resume_entry.type() == lazy_entry::dict_t)
{
using namespace libtorrent::detail; // for read_*_endpoint()
peer_id id(0);
if (lazy_entry const* peers_entry = m_resume_entry.dict_find_string("peers"))
{
int num_peers = peers_entry->string_length() / (sizeof(address_v4::bytes_type) + 2);
char const* ptr = peers_entry->string_ptr();
for (int i = 0; i < num_peers; ++i)
{
m_policy.add_peer(read_v4_endpoint<tcp::endpoint>(ptr)
, id, peer_info::resume_data, 0);
}
}
if (lazy_entry const* banned_peers_entry = m_resume_entry.dict_find_string("banned_peers"))
{
int num_peers = banned_peers_entry->string_length() / (sizeof(address_v4::bytes_type) + 2);
char const* ptr = banned_peers_entry->string_ptr();
for (int i = 0; i < num_peers; ++i)
{
policy::peer* p = m_policy.add_peer(read_v4_endpoint<tcp::endpoint>(ptr)
, id, peer_info::resume_data, 0);
if (p) m_policy.ban_peer(p);
}
}
#if TORRENT_USE_IPV6
if (lazy_entry const* peers6_entry = m_resume_entry.dict_find_string("peers6"))
{
int num_peers = peers6_entry->string_length() / (sizeof(address_v6::bytes_type) + 2);
char const* ptr = peers6_entry->string_ptr();
for (int i = 0; i < num_peers; ++i)
{
m_policy.add_peer(read_v6_endpoint<tcp::endpoint>(ptr)
, id, peer_info::resume_data, 0);
}
}
if (lazy_entry const* banned_peers6_entry = m_resume_entry.dict_find_string("banned_peers6"))
{
int num_peers = banned_peers6_entry->string_length() / (sizeof(address_v6::bytes_type) + 2);
char const* ptr = banned_peers6_entry->string_ptr();
for (int i = 0; i < num_peers; ++i)
{
policy::peer* p = m_policy.add_peer(read_v6_endpoint<tcp::endpoint>(ptr)
, id, peer_info::resume_data, 0);
if (p) m_policy.ban_peer(p);
}
}
#endif
// parse out "peers" from the resume data and add them to the peer list
if (lazy_entry const* peers_entry = m_resume_entry.dict_find_list("peers"))
{
for (int i = 0; i < peers_entry->list_size(); ++i)
{
lazy_entry const* e = peers_entry->list_at(i);
if (e->type() != lazy_entry::dict_t) continue;
std::string ip = e->dict_find_string_value("ip");
int port = e->dict_find_int_value("port");
if (ip.empty() || port == 0) continue;
error_code ec;
tcp::endpoint a(address::from_string(ip, ec), (unsigned short)port);
if (ec) continue;
m_policy.add_peer(a, id, peer_info::resume_data, 0);
}
}
// parse out "banned_peers" and add them as banned
if (lazy_entry const* banned_peers_entry = m_resume_entry.dict_find_list("banned_peers"))
{
for (int i = 0; i < banned_peers_entry->list_size(); ++i)
{
lazy_entry const* e = banned_peers_entry->list_at(i);
if (e->type() != lazy_entry::dict_t) continue;
std::string ip = e->dict_find_string_value("ip");
int port = e->dict_find_int_value("port");
if (ip.empty() || port == 0) continue;
error_code ec;
tcp::endpoint a(address::from_string(ip, ec), (unsigned short)port);
if (ec) continue;
policy::peer* p = m_policy.add_peer(a, id, peer_info::resume_data, 0);
if (p) m_policy.ban_peer(p);
}
}
}
if (j.error && m_ses.m_alerts.should_post<fastresume_rejected_alert>())
{
m_ses.m_alerts.post_alert(fastresume_rejected_alert(get_handle(), j.error));
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << "fastresume data for "
<< torrent_file().name() << " rejected: "
<< j.error.message() << "\n";
#endif
if (ret == 0)
{
// there are either no files for this torrent
// or the resume_data was accepted
if (!j.error && m_resume_entry.type() == lazy_entry::dict_t)
{
// parse have bitmask
lazy_entry const* pieces = m_resume_entry.dict_find("pieces");
if (pieces && pieces->type() == lazy_entry::string_t
&& int(pieces->string_length()) == m_torrent_file->num_pieces())
{
char const* pieces_str = pieces->string_ptr();
for (int i = 0, end(pieces->string_length()); i < end; ++i)
{
if (pieces_str[i] & 1) we_have(i);
if (m_seed_mode && (pieces_str[i] & 2)) m_verified.set_bit(i);
}
}
else
{
lazy_entry const* slots = m_resume_entry.dict_find("slots");
if (slots && slots->type() == lazy_entry::list_t)
{
for (int i = 0; i < slots->list_size(); ++i)
{
int piece = slots->list_int_value_at(i, -1);
if (piece >= 0) we_have(piece);
}
}
}
// parse unfinished pieces
int num_blocks_per_piece =
static_cast<int>(torrent_file().piece_length()) / block_size();
if (lazy_entry const* unfinished_ent = m_resume_entry.dict_find_list("unfinished"))
{
for (int i = 0; i < unfinished_ent->list_size(); ++i)
{
lazy_entry const* e = unfinished_ent->list_at(i);
if (e->type() != lazy_entry::dict_t) continue;
int piece = e->dict_find_int_value("piece", -1);
if (piece < 0 || piece > torrent_file().num_pieces()) continue;
if (m_picker->have_piece(piece))
m_picker->we_dont_have(piece);
std::string bitmask = e->dict_find_string_value("bitmask");
if (bitmask.empty()) continue;
const int num_bitmask_bytes = (std::max)(num_blocks_per_piece / 8, 1);
if ((int)bitmask.size() != num_bitmask_bytes) continue;
for (int j = 0; j < num_bitmask_bytes; ++j)
{
unsigned char bits = bitmask[j];
int num_bits = (std::min)(num_blocks_per_piece - j*8, 8);
for (int k = 0; k < num_bits; ++k)
{
const int bit = j * 8 + k;
if (bits & (1 << k))
{
m_picker->mark_as_finished(piece_block(piece, bit), 0);
if (m_picker->is_piece_finished(piece))
async_verify_piece(piece, bind(&torrent::piece_finished
, shared_from_this(), piece, _1));
}
}
}
}
}
}
files_checked(l);
}
else
{
// either the fastresume data was rejected or there are
// some files
set_state(torrent_status::queued_for_checking);
if (should_check_files())
queue_torrent_check();
}
std::vector<char>().swap(m_resume_data);
lazy_entry().swap(m_resume_entry);
}
void torrent::queue_torrent_check()
{
if (m_queued_for_checking) return;
m_queued_for_checking = true;
m_ses.queue_check_torrent(shared_from_this());
}
void torrent::dequeue_torrent_check()
{
if (!m_queued_for_checking) return;
m_queued_for_checking = false;
m_ses.dequeue_check_torrent(shared_from_this());
}
void torrent::force_recheck()
{
if (!valid_metadata()) return;
// if the torrent is already queued to check its files
// don't do anything
if (should_check_files()
|| m_state == torrent_status::checking_resume_data)
return;
clear_error();
disconnect_all(errors::stopping_torrent);
stop_announcing();
m_owning_storage->async_release_files();
if (!m_picker) m_picker.reset(new piece_picker());
std::fill(m_file_progress.begin(), m_file_progress.end(), 0);
int blocks_per_piece = (m_torrent_file->piece_length() + block_size() - 1) / block_size();
int blocks_in_last_piece = ((m_torrent_file->total_size() % m_torrent_file->piece_length())
+ block_size() - 1) / block_size();
m_picker->init(blocks_per_piece, blocks_in_last_piece, m_torrent_file->num_pieces());
// assume that we don't have anything
TORRENT_ASSERT(m_picker->num_have() == 0);
m_files_checked = false;
set_state(torrent_status::checking_resume_data);
m_policy.recalculate_connect_candidates();
if (m_auto_managed && !is_finished())
set_queue_position((std::numeric_limits<int>::max)());
std::vector<char>().swap(m_resume_data);
lazy_entry().swap(m_resume_entry);
m_storage->async_check_fastresume(&m_resume_entry
, bind(&torrent::on_force_recheck
, shared_from_this(), _1, _2));
}
void torrent::on_force_recheck(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
if (ret == piece_manager::fatal_disk_error)
{
handle_disk_error(j);
return;
}
if (ret == 0)
{
// if there are no files, just start
files_checked(l);
}
else
{
set_state(torrent_status::queued_for_checking);
if (should_check_files())
queue_torrent_check();
}
}
void torrent::start_checking()
{
TORRENT_ASSERT(should_check_files());
set_state(torrent_status::checking_files);
m_storage->async_check_files(bind(
&torrent::on_piece_checked
, shared_from_this(), _1, _2));
}
void torrent::on_piece_checked(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
if (ret == piece_manager::disk_check_aborted)
{
dequeue_torrent_check();
pause();
return;
}
if (ret == piece_manager::fatal_disk_error)
{
if (m_ses.m_alerts.should_post<file_error_alert>())
{
m_ses.m_alerts.post_alert(file_error_alert(j.error_file, get_handle(), j.error));
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << time_now_string() << ": fatal disk error ["
" error: " << j.str <<
" torrent: " << torrent_file().name() <<
" ]\n";
#endif
pause();
set_error(j.error, j.error_file);
return;
}
m_progress_ppm = size_type(j.piece) * 1000000 / torrent_file().num_pieces();
TORRENT_ASSERT(m_picker);
if (j.offset >= 0 && !m_picker->have_piece(j.offset))
we_have(j.offset);
remove_time_critical_piece(j.piece);
// we're not done checking yet
// this handler will be called repeatedly until
// we're done, or encounter a failure
if (ret == piece_manager::need_full_check) return;
dequeue_torrent_check();
files_checked(l);
}
void torrent::use_interface(const char* net_interface)
{
INVARIANT_CHECK;
error_code ec;
address a(address::from_string(net_interface, ec));
if (ec) return;
m_net_interface = tcp::endpoint(a, 0);
}
void torrent::on_tracker_announce_disp(boost::weak_ptr<torrent> p
, error_code const& e)
{
if (e) return;
boost::shared_ptr<torrent> t = p.lock();
if (!t) return;
t->on_tracker_announce();
}
void torrent::on_tracker_announce()
{
mutex::scoped_lock l(m_ses.m_mutex);
m_waiting_tracker = false;
if (m_abort) return;
announce_with_tracker();
}
void torrent::lsd_announce()
{
if (m_abort) return;
// if the files haven't been checked yet, we're
// not ready for peers
if (!m_files_checked) return;
TORRENT_ASSERT(!m_torrent_file->priv());
if (m_torrent_file->is_valid()
&& (m_torrent_file->priv()
|| (torrent_file().is_i2p()
&& !settings().allow_i2p_mixed)))
return;
if (is_paused()) return;
// announce with the local discovery service
m_ses.announce_lsd(m_torrent_file->info_hash());
}
#ifndef TORRENT_DISABLE_DHT
void torrent::dht_announce()
{
if (m_torrent_file->is_valid() && m_torrent_file->priv())
return;
if (is_paused()) return;
if (!m_ses.m_dht) return;
if (!should_announce_dht()) return;
boost::weak_ptr<torrent> self(shared_from_this());
m_ses.m_dht->announce(m_torrent_file->info_hash()
, m_ses.listen_port()
, bind(&torrent::on_dht_announce_response_disp, self, _1));
}
void torrent::on_dht_announce_response_disp(boost::weak_ptr<libtorrent::torrent> t
, std::vector<tcp::endpoint> const& peers)
{
boost::shared_ptr<libtorrent::torrent> tor = t.lock();
if (!tor) return;
tor->on_dht_announce_response(peers);
}
void torrent::on_dht_announce_response(std::vector<tcp::endpoint> const& peers)
{
if (peers.empty()) return;
if (m_ses.m_alerts.should_post<dht_reply_alert>())
{
m_ses.m_alerts.post_alert(dht_reply_alert(
get_handle(), peers.size()));
}
if (torrent_file().priv() || (torrent_file().is_i2p()
&& !settings().allow_i2p_mixed)) return;
std::for_each(peers.begin(), peers.end(), bind(
&policy::add_peer, boost::ref(m_policy), _1, peer_id(0)
, peer_info::dht, 0));
}
#endif
void torrent::announce_with_tracker(tracker_request::event_t e
, address const& bind_interface)
{
INVARIANT_CHECK;
if (m_trackers.empty()) return;
if (m_abort) e = tracker_request::stopped;
tracker_request req;
req.info_hash = m_torrent_file->info_hash();
req.pid = m_ses.get_peer_id();
req.downloaded = m_stat.total_payload_download() - m_total_failed_bytes;
req.uploaded = m_stat.total_payload_upload();
req.corrupt = m_total_failed_bytes;
req.left = bytes_left();
if (req.left == -1) req.left = 16*1024;
// exclude redundant bytes if we should
if (!settings().report_true_downloaded)
req.downloaded -= m_total_redundant_bytes;
req.event = e;
error_code ec;
tcp::endpoint ep;
ep = m_ses.get_ipv6_interface();
if (ep != tcp::endpoint()) req.ipv6 = ep.address().to_string(ec);
ep = m_ses.get_ipv4_interface();
if (ep != tcp::endpoint()) req.ipv4 = ep.address().to_string(ec);
// if we are aborting. we don't want any new peers
req.num_want = (req.event == tracker_request::stopped)
?0:settings().num_want;
req.listen_port = m_ses.listen_port();
req.key = m_ses.m_key;
ptime now = time_now();
// the tier is kept as INT_MAX until we find the first
// tracker that works, then it's set to that tracker's
// tier.
int tier = INT_MAX;
// have we sent an announce in this tier yet?
bool sent_announce = false;
for (int i = 0; i < int(m_trackers.size()); ++i)
{
announce_entry& ae = m_trackers[i];
if (settings().announce_to_all_tiers
&& !settings().announce_to_all_trackers
&& sent_announce
&& ae.tier <= tier
&& tier != INT_MAX)
continue;
if (ae.tier > tier && !settings().announce_to_all_tiers) break;
if (ae.is_working()) { tier = ae.tier; sent_announce = false; }
if (!ae.can_announce(now))
{
if (ae.is_working())
{
sent_announce = true; // this counts
if (!settings().announce_to_all_trackers
&& !settings().announce_to_all_tiers)
break;
}
continue;
}
req.url = ae.url;
req.event = e;
if (req.event == tracker_request::none)
{
if (!ae.start_sent) req.event = tracker_request::started;
else if (!ae.complete_sent && is_seed()) req.event = tracker_request::completed;
}
if (!is_any(bind_interface)) req.bind_ip = bind_interface;
else req.bind_ip = m_ses.m_listen_interface.address();
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " ==> TACKER REQUEST " << req.url
<< " event=" << (req.event==tracker_request::stopped?"stopped"
:req.event==tracker_request::started?"started":"")
<< " abort=" << m_abort << "\n";
if (m_abort)
{
boost::shared_ptr<aux::tracker_logger> tl(new aux::tracker_logger(m_ses));
m_ses.m_tracker_manager.queue_request(m_ses.m_io_service, m_ses.m_half_open, req
, tracker_login(), tl);
}
else
#endif
m_ses.m_tracker_manager.queue_request(m_ses.m_io_service, m_ses.m_half_open, req
, tracker_login() , m_abort?boost::shared_ptr<torrent>():shared_from_this());
ae.updating = true;
if (m_ses.m_alerts.should_post<tracker_announce_alert>())
{
m_ses.m_alerts.post_alert(
tracker_announce_alert(get_handle(), req.url, req.event));
}
sent_announce = true;
if (ae.is_working()
&& !settings().announce_to_all_trackers
&& !settings().announce_to_all_tiers)
break;
}
update_tracker_timer();
}
void torrent::scrape_tracker()
{
m_last_scrape = 0;
if (m_trackers.empty()) return;
int i = m_last_working_tracker;
if (i == -1) i = 0;
tracker_request req;
req.info_hash = m_torrent_file->info_hash();
req.kind = tracker_request::scrape_request;
req.url = m_trackers[i].url;
req.bind_ip = m_ses.m_listen_interface.address();
m_ses.m_tracker_manager.queue_request(m_ses.m_io_service, m_ses.m_half_open, req
, tracker_login(), shared_from_this());
}
void torrent::tracker_warning(tracker_request const& req, std::string const& msg)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
if (m_ses.m_alerts.should_post<tracker_warning_alert>())
m_ses.m_alerts.post_alert(tracker_warning_alert(get_handle(), req.url, msg));
}
void torrent::tracker_scrape_response(tracker_request const& req
, int complete, int incomplete, int downloaded)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
TORRENT_ASSERT(req.kind == tracker_request::scrape_request);
if (complete >= 0) m_complete = complete;
if (incomplete >= 0) m_incomplete = incomplete;
if (m_ses.m_alerts.should_post<scrape_reply_alert>())
{
m_ses.m_alerts.post_alert(scrape_reply_alert(
get_handle(), m_incomplete, m_complete, req.url));
}
}
void torrent::tracker_response(
tracker_request const& r
, address const& tracker_ip // this is the IP we connected to
, std::list<address> const& tracker_ips // these are all the IPs it resolved to
, std::vector<peer_entry>& peer_list
, int interval
, int min_interval
, int complete
, int incomplete
, address const& external_ip)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
TORRENT_ASSERT(r.kind == tracker_request::announce_request);
if (external_ip != address())
m_ses.set_external_address(external_ip);
ptime now = time_now();
if (interval < settings().min_announce_interval)
interval = settings().min_announce_interval;
announce_entry* ae = find_tracker(r);
if (ae)
{
if (!ae->start_sent && r.event == tracker_request::started)
ae->start_sent = true;
if (!ae->complete_sent && r.event == tracker_request::completed)
ae->complete_sent = true;
ae->verified = true;
ae->updating = false;
ae->fails = 0;
ae->next_announce = now + seconds(interval);
ae->min_announce = now + seconds(min_interval);
int tracker_index = ae - &m_trackers[0];
m_last_working_tracker = prioritize_tracker(tracker_index);
}
update_tracker_timer();
if (complete >= 0) m_complete = complete;
if (incomplete >= 0) m_incomplete = incomplete;
if (complete >= 0 && incomplete >= 0)
m_last_scrape = 0;
#if (defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING) && TORRENT_USE_IOSTREAM
std::stringstream s;
s << "TRACKER RESPONSE:\n"
"interval: " << interval << "\n"
"peers:\n";
for (std::vector<peer_entry>::const_iterator i = peer_list.begin();
i != peer_list.end(); ++i)
{
s << " " << std::setfill(' ') << std::setw(16) << i->ip
<< " " << std::setw(5) << std::dec << i->port << " ";
if (!i->pid.is_all_zeros()) s << " " << i->pid << " " << identify_client(i->pid);
s << "\n";
}
s << "external ip: " << external_ip << "\n";
s << "tracker ips: ";
std::copy(tracker_ips.begin(), tracker_ips.end(), std::ostream_iterator<address>(s, " "));
s << "\n";
s << "we connected to: " << tracker_ip << "\n";
debug_log(s.str());
#endif
// for each of the peers we got from the tracker
for (std::vector<peer_entry>::iterator i = peer_list.begin();
i != peer_list.end(); ++i)
{
// don't make connections to ourself
if (i->pid == m_ses.get_peer_id())
continue;
error_code ec;
tcp::endpoint a(address::from_string(i->ip, ec), i->port);
if (ec)
{
// assume this is because we got a hostname instead of
// an ip address from the tracker
#if TORRENT_USE_I2P
char const* top_domain = strrchr(i->ip.c_str(), '.');
if (top_domain && strcmp(top_domain, ".i2p") == 0 && m_ses.m_i2p_conn.is_open())
{
// this is an i2p name, we need to use the sam connection
// to do the name lookup
/*
m_ses.m_i2p_conn.async_name_lookup(i->ip.c_str()
, bind(&torrent::on_i2p_resolve
, shared_from_this(), _1, _2));
*/
// it seems like you're not supposed to do a name lookup
// on the peers returned from the tracker, but just strip
// the .i2p and use it as a destination
i->ip.resize(i->ip.size() - 4);
m_policy.add_i2p_peer(i->ip.c_str(), peer_info::tracker, 0);
}
else
#endif
{
tcp::resolver::query q(i->ip, to_string(i->port).elems);
m_ses.m_host_resolver.async_resolve(q,
bind(&torrent::on_peer_name_lookup, shared_from_this(), _1, _2, i->pid));
}
}
else
{
// ignore local addresses from the tracker (unless the tracker is local too)
if (is_local(a.address()) && !is_local(tracker_ip)) continue;
m_policy.add_peer(a, i->pid, peer_info::tracker, 0);
}
}
if (m_ses.m_alerts.should_post<tracker_reply_alert>())
{
m_ses.m_alerts.post_alert(tracker_reply_alert(
get_handle(), peer_list.size(), r.url));
}
m_got_tracker_response = true;
// we're listening on an interface type that was not used
// when talking to the tracker. If there is a matching interface
// type in the tracker IP list, make another tracker request
// using that interface
// in order to avoid triggering this case over and over, don't
// do it if the bind IP for the tracker request that just completed
// matches one of the listen interfaces, since that means this
// announce was the second one
// don't connect twice just to tell it we're stopping
if (((!is_any(m_ses.m_ipv6_interface.address()) && tracker_ip.is_v4())
|| (!is_any(m_ses.m_ipv4_interface.address()) && tracker_ip.is_v6()))
&& r.bind_ip != m_ses.m_ipv4_interface.address()
&& r.bind_ip != m_ses.m_ipv6_interface.address()
&& r.event != tracker_request::stopped)
{
std::list<address>::const_iterator i = std::find_if(tracker_ips.begin()
, tracker_ips.end(), boost::bind(&address::is_v4, _1) != tracker_ip.is_v4());
if (i != tracker_ips.end())
{
// the tracker did resolve to a different type if address, so announce
// to that as well
// tell the tracker to bind to the opposite protocol type
address bind_interface = tracker_ip.is_v4()
?m_ses.m_ipv6_interface.address()
:m_ses.m_ipv4_interface.address();
announce_with_tracker(r.event, bind_interface);
#if (defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING) && TORRENT_USE_IOSTREAM
debug_log("announce again using " + print_address(bind_interface)
+ " as the bind interface");
#endif
}
}
}
ptime torrent::next_announce() const
{
return m_waiting_tracker?m_tracker_timer.expires_at():min_time();
}
void torrent::force_tracker_request()
{
if (is_paused()) return;
ptime now = time_now();
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
i->next_announce = (std::max)(now, i->min_announce);
update_tracker_timer();
}
void torrent::force_tracker_request(ptime t)
{
if (is_paused()) return;
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
i->next_announce = (std::max)(t, i->min_announce);
update_tracker_timer();
}
void torrent::set_tracker_login(
std::string const& name
, std::string const& pw)
{
m_username = name;
m_password = pw;
}
#if TORRENT_USE_I2P
void torrent::on_i2p_resolve(error_code const& ec, char const* dest)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
#if defined TORRENT_LOGGING
if (ec)
*m_ses.m_logger << time_now_string() << " on_i2p_resolve: " << ec.message() << "\n";
#endif
if (ec || m_ses.is_aborted()) return;
m_policy.add_i2p_peer(dest, peer_info::tracker, 0);
}
#endif
void torrent::on_peer_name_lookup(error_code const& e, tcp::resolver::iterator host
, peer_id pid)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
#if defined TORRENT_LOGGING
if (e)
*m_ses.m_logger << time_now_string() << " on_peer_name_lookup: " << e.message() << "\n";
#endif
if (e || host == tcp::resolver::iterator() ||
m_ses.is_aborted()) return;
if (m_ses.m_ip_filter.access(host->endpoint().address()) & ip_filter::blocked)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
error_code ec;
debug_log("blocked ip from tracker: " + host->endpoint().address().to_string(ec));
#endif
if (m_ses.m_alerts.should_post<peer_blocked_alert>())
m_ses.m_alerts.post_alert(peer_blocked_alert(get_handle(), host->endpoint().address()));
return;
}
m_policy.add_peer(*host, pid, peer_info::tracker, 0);
}
size_type torrent::bytes_left() const
{
// if we don't have the metadata yet, we
// cannot tell how big the torrent is.
if (!valid_metadata()) return -1;
return m_torrent_file->total_size()
- quantized_bytes_done();
}
size_type torrent::quantized_bytes_done() const
{
// INVARIANT_CHECK;
if (!valid_metadata()) return 0;
if (m_torrent_file->num_pieces() == 0)
return 0;
if (is_seed()) return m_torrent_file->total_size();
const int last_piece = m_torrent_file->num_pieces() - 1;
size_type total_done
= size_type(num_have()) * m_torrent_file->piece_length();
// if we have the last piece, we have to correct
// the amount we have, since the first calculation
// assumed all pieces were of equal size
if (m_picker->have_piece(last_piece))
{
int corr = m_torrent_file->piece_size(last_piece)
- m_torrent_file->piece_length();
total_done += corr;
}
return total_done;
}
// returns the number of bytes we are interested
// in for the given block. This returns block_size()
// for all blocks except the last one (if it's smaller
// than block_size()) and blocks that overlap a padding
// file
int torrent::block_bytes_wanted(piece_block const& p) const
{
file_storage const& fs = m_torrent_file->files();
int piece_size = m_torrent_file->piece_size(p.piece_index);
int offset = p.block_index * block_size();
if (m_padding == 0) return (std::min)(piece_size - offset, int(block_size()));
std::vector<file_slice> files = fs.map_block(
p.piece_index, offset, (std::min)(piece_size - offset, int(block_size())));
int ret = 0;
for (std::vector<file_slice>::iterator i = files.begin()
, end(files.end()); i != end; ++i)
{
file_entry const& fe = fs.at(i->file_index);
if (fe.pad_file) continue;
ret += i->size;
}
TORRENT_ASSERT(ret <= (std::min)(piece_size - offset, int(block_size())));
return ret;
}
// fills in total_wanted, total_wanted_done and total_done
void torrent::bytes_done(torrent_status& st, bool accurate) const
{
INVARIANT_CHECK;
st.total_done = 0;
st.total_wanted_done = 0;
st.total_wanted = m_torrent_file->total_size();
TORRENT_ASSERT(st.total_wanted >= m_padding);
TORRENT_ASSERT(st.total_wanted >= 0);
if (!valid_metadata() || m_torrent_file->num_pieces() == 0)
return;
TORRENT_ASSERT(st.total_wanted >= m_torrent_file->piece_length()
* (m_torrent_file->num_pieces() - 1));
const int last_piece = m_torrent_file->num_pieces() - 1;
const int piece_size = m_torrent_file->piece_length();
if (is_seed())
{
st.total_done = m_torrent_file->total_size() - m_padding;
st.total_wanted_done = st.total_done;
st.total_wanted = st.total_done;
return;
}
TORRENT_ASSERT(num_have() >= m_picker->num_have_filtered());
st.total_wanted_done = size_type(num_have() - m_picker->num_have_filtered())
* piece_size;
TORRENT_ASSERT(st.total_wanted_done >= 0);
st.total_done = size_type(num_have()) * piece_size;
TORRENT_ASSERT(num_have() < m_torrent_file->num_pieces());
int num_filtered_pieces = m_picker->num_filtered()
+ m_picker->num_have_filtered();
int last_piece_index = m_torrent_file->num_pieces() - 1;
if (m_picker->piece_priority(last_piece_index) == 0)
{
st.total_wanted -= m_torrent_file->piece_size(last_piece_index);
--num_filtered_pieces;
}
st.total_wanted -= size_type(num_filtered_pieces) * piece_size;
// if we have the last piece, we have to correct
// the amount we have, since the first calculation
// assumed all pieces were of equal size
if (m_picker->have_piece(last_piece))
{
TORRENT_ASSERT(st.total_done >= piece_size);
int corr = m_torrent_file->piece_size(last_piece)
- piece_size;
TORRENT_ASSERT(corr <= 0);
TORRENT_ASSERT(corr > -piece_size);
st.total_done += corr;
if (m_picker->piece_priority(last_piece) != 0)
{
TORRENT_ASSERT(st.total_wanted_done >= piece_size);
st.total_wanted_done += corr;
}
}
TORRENT_ASSERT(st.total_wanted >= st.total_wanted_done);
// subtract padding files
if (m_padding > 0)
{
file_storage const& files = m_torrent_file->files();
int fileno = 0;
for (file_storage::iterator i = files.begin()
, end(files.end()); i != end; ++i, ++fileno)
{
if (!i->pad_file) continue;
peer_request p = files.map_file(fileno, 0, i->size);
for (int j = p.piece; p.length > 0; ++j, p.length -= piece_size)
{
int deduction = (std::min)(p.length, piece_size);
bool done = m_picker->have_piece(j);
bool wanted = m_picker->piece_priority(j) > 0;
if (done) st.total_done -= deduction;
if (wanted) st.total_wanted -= deduction;
if (wanted && done) st.total_wanted_done -= deduction;
}
}
}
TORRENT_ASSERT(st.total_done <= m_torrent_file->total_size() - m_padding);
TORRENT_ASSERT(st.total_wanted_done <= m_torrent_file->total_size() - m_padding);
TORRENT_ASSERT(st.total_wanted_done >= 0);
TORRENT_ASSERT(st.total_done >= st.total_wanted_done);
// this is expensive, we might not want to do it all the time
if (!accurate) return;
const std::vector<piece_picker::downloading_piece>& dl_queue
= m_picker->get_download_queue();
const int blocks_per_piece = (piece_size + block_size() - 1) / block_size();
// look at all unfinished pieces and add the completed
// blocks to our 'done' counter
for (std::vector<piece_picker::downloading_piece>::const_iterator i =
dl_queue.begin(); i != dl_queue.end(); ++i)
{
int corr = 0;
int index = i->index;
// completed pieces are already accounted for
if (m_picker->have_piece(index)) continue;
TORRENT_ASSERT(i->finished <= m_picker->blocks_in_piece(index));
#ifdef TORRENT_DEBUG
for (std::vector<piece_picker::downloading_piece>::const_iterator j = boost::next(i);
j != dl_queue.end(); ++j)
{
TORRENT_ASSERT(j->index != index);
}
#endif
for (int j = 0; j < blocks_per_piece; ++j)
{
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
TORRENT_ASSERT(m_picker->is_finished(piece_block(index, j))
== (i->info[j].state == piece_picker::block_info::state_finished));
#endif
if (i->info[j].state == piece_picker::block_info::state_finished)
{
corr += block_bytes_wanted(piece_block(index, j));
}
TORRENT_ASSERT(corr >= 0);
TORRENT_ASSERT(index != last_piece || j < m_picker->blocks_in_last_piece()
|| i->info[j].state != piece_picker::block_info::state_finished);
}
st.total_done += corr;
if (m_picker->piece_priority(index) > 0)
st.total_wanted_done += corr;
}
TORRENT_ASSERT(st.total_wanted <= m_torrent_file->total_size() - m_padding);
TORRENT_ASSERT(st.total_done <= m_torrent_file->total_size() - m_padding);
TORRENT_ASSERT(st.total_wanted_done <= m_torrent_file->total_size() - m_padding);
TORRENT_ASSERT(st.total_wanted_done >= 0);
TORRENT_ASSERT(st.total_done >= st.total_wanted_done);
std::map<piece_block, int> downloading_piece;
for (const_peer_iterator i = begin(); i != end(); ++i)
{
peer_connection* pc = *i;
boost::optional<piece_block_progress> p
= pc->downloading_piece_progress();
if (!p) continue;
if (m_picker->have_piece(p->piece_index))
continue;
piece_block block(p->piece_index, p->block_index);
if (m_picker->is_finished(block))
continue;
std::map<piece_block, int>::iterator dp
= downloading_piece.find(block);
if (dp != downloading_piece.end())
{
if (dp->second < p->bytes_downloaded)
dp->second = p->bytes_downloaded;
}
else
{
downloading_piece[block] = p->bytes_downloaded;
}
#ifdef TORRENT_DEBUG
TORRENT_ASSERT(p->bytes_downloaded <= p->full_block_bytes);
TORRENT_ASSERT(p->full_block_bytes == to_req(piece_block(
p->piece_index, p->block_index)).length);
#endif
}
for (std::map<piece_block, int>::iterator i = downloading_piece.begin();
i != downloading_piece.end(); ++i)
{
int done = (std::min)(block_bytes_wanted(i->first), i->second);
st.total_done += done;
if (m_picker->piece_priority(i->first.piece_index) != 0)
st.total_wanted_done += done;
}
TORRENT_ASSERT(st.total_done <= m_torrent_file->total_size() - m_padding);
TORRENT_ASSERT(st.total_wanted_done <= m_torrent_file->total_size() - m_padding);
#ifdef TORRENT_DEBUG
if (st.total_done >= m_torrent_file->total_size())
{
// Thist happens when a piece has been downloaded completely
// but not yet verified against the hash
fprintf(stderr, "num_have: %d\nunfinished:\n", num_have());
for (std::vector<piece_picker::downloading_piece>::const_iterator i =
dl_queue.begin(); i != dl_queue.end(); ++i)
{
fprintf(stderr, " %d ", i->index);
for (int j = 0; j < blocks_per_piece; ++j)
{
char const* state = i->info[j].state == piece_picker::block_info::state_finished ? "1" : "0";
fputs(state, stderr);
}
fputs("\n", stderr);
}
fputs("downloading pieces:\n", stderr);
for (std::map<piece_block, int>::iterator i = downloading_piece.begin();
i != downloading_piece.end(); ++i)
{
fprintf(stderr, " %d:%d %d\n", i->first.piece_index, i->first.block_index, i->second);
}
}
TORRENT_ASSERT(st.total_done <= m_torrent_file->total_size());
TORRENT_ASSERT(st.total_wanted_done <= m_torrent_file->total_size());
#endif
TORRENT_ASSERT(st.total_done >= st.total_wanted_done);
}
// passed_hash_check
// 0: success, piece passed check
// -1: disk failure
// -2: piece failed check
void torrent::piece_finished(int index, int passed_hash_check)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " *** PIECE_FINISHED [ p: "
<< index << " chk: " << ((passed_hash_check == 0)
?"passed":passed_hash_check == -1
?"disk failed":"failed") << " ]\n";
#endif
TORRENT_ASSERT(valid_metadata());
// even though the piece passed the hash-check
// it might still have failed being written to disk
// if so, piece_picker::write_failed() has been
// called, and the piece is no longer finished.
// in this case, we have to ignore the fact that
// it passed the check
if (!m_picker->is_piece_finished(index)) return;
if (passed_hash_check == 0)
{
// the following call may cause picker to become invalid
// in case we just became a seed
piece_passed(index);
// if we're in seed mode, we just acquired this piece
// mark it as verified
if (m_seed_mode) verified(index);
}
else if (passed_hash_check == -2)
{
// piece_failed() will restore the piece
piece_failed(index);
}
else
{
TORRENT_ASSERT(passed_hash_check == -1);
m_picker->restore_piece(index);
restore_piece_state(index);
}
}
void torrent::update_sparse_piece_prio(int i, int start, int end)
{
TORRENT_ASSERT(m_picker);
if (m_picker->have_piece(i) || m_picker->piece_priority(i) == 0)
return;
bool have_before = i == 0 || m_picker->have_piece(i - 1);
bool have_after = i == end - 1 || m_picker->have_piece(i + 1);
if (have_after && have_before)
m_picker->set_piece_priority(i, 7);
else if (have_after || have_before)
m_picker->set_piece_priority(i, 6);
}
void torrent::we_have(int index)
{
// update m_file_progress
TORRENT_ASSERT(m_picker);
TORRENT_ASSERT(!have_piece(index));
const int piece_size = m_torrent_file->piece_length();
size_type off = size_type(index) * piece_size;
file_storage::iterator f = m_torrent_file->files().file_at_offset(off);
int size = m_torrent_file->piece_size(index);
int file_index = f - m_torrent_file->files().begin();
for (; size > 0; ++f, ++file_index)
{
size_type file_offset = off - f->offset;
TORRENT_ASSERT(f != m_torrent_file->files().end());
TORRENT_ASSERT(file_offset <= f->size);
int add = (std::min)(f->size - file_offset, (size_type)size);
m_file_progress[file_index] += add;
TORRENT_ASSERT(m_file_progress[file_index]
<= m_torrent_file->files().at(file_index).size);
if (m_file_progress[file_index] >= m_torrent_file->files().at(file_index).size)
{
filesystem().async_finalize_file(file_index);
if (m_ses.m_alerts.should_post<piece_finished_alert>())
{
// this file just completed, post alert
m_ses.m_alerts.post_alert(file_completed_alert(get_handle()
, file_index));
}
}
size -= add;
off += add;
TORRENT_ASSERT(size >= 0);
}
m_picker->we_have(index);
}
void torrent::piece_passed(int index)
{
// INVARIANT_CHECK;
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < m_torrent_file->num_pieces());
if (m_ses.m_alerts.should_post<piece_finished_alert>())
{
m_ses.m_alerts.post_alert(piece_finished_alert(get_handle()
, index));
}
remove_time_critical_piece(index, true);
bool was_finished = m_picker->num_filtered() + num_have()
== torrent_file().num_pieces();
std::vector<void*> downloaders;
m_picker->get_downloaders(downloaders, index);
// increase the trust point of all peers that sent
// parts of this piece.
std::set<void*> peers;
std::copy(downloaders.begin(), downloaders.end(), std::inserter(peers, peers.begin()));
we_have(index);
for (peer_iterator i = m_connections.begin(); i != m_connections.end();)
{
peer_connection* p = *i;
++i;
p->announce_piece(index);
}
for (std::set<void*>::iterator i = peers.begin()
, end(peers.end()); i != end; ++i)
{
policy::peer* p = static_cast<policy::peer*>(*i);
if (p == 0) continue;
p->on_parole = false;
int trust_points = p->trust_points;
++trust_points;
if (trust_points > 8) trust_points = 8;
p->trust_points = trust_points;
if (p->connection) p->connection->received_valid_data(index);
}
if (settings().max_sparse_regions > 0
&& m_picker->sparse_regions() > settings().max_sparse_regions)
{
// we have too many sparse regions. Prioritize pieces
// that won't introduce new sparse regions
// prioritize pieces that will reduce the number of sparse
// regions even higher
int start = m_picker->cursor();
int end = m_picker->reverse_cursor();
if (index > start) update_sparse_piece_prio(index - 1, start, end);
if (index < end - 1) update_sparse_piece_prio(index + 1, start, end);
}
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
#ifndef BOOST_NO_EXCEPTIONS
try {
#endif
(*i)->on_piece_pass(index);
#ifndef BOOST_NO_EXCEPTIONS
} catch (std::exception&) {}
#endif
}
#endif
// since this piece just passed, we might have
// become uninterested in some peers where this
// was the last piece we were interested in
for (peer_iterator i = m_connections.begin();
i != m_connections.end();)
{
peer_connection* p = *i;
// update_interest may disconnect the peer and
// invalidate the iterator
++i;
// if we're not interested already, no need to check
if (!p->is_interesting()) continue;
// if the peer doesn't have the piece we just got, it
// wouldn't affect our interest
if (!p->has_piece(index)) continue;
p->update_interest();
}
if (!was_finished && is_finished())
{
// torrent finished
// i.e. all the pieces we're interested in have
// been downloaded. Release the files (they will open
// in read only mode if needed)
finished();
// if we just became a seed, picker is now invalid, since it
// is deallocated by the torrent once it starts seeding
}
}
void torrent::piece_failed(int index)
{
// if the last piece fails the peer connection will still
// think that it has received all of it until this function
// resets the download queue. So, we cannot do the
// invariant check here since it assumes:
// (total_done == m_torrent_file->total_size()) => is_seed()
INVARIANT_CHECK;
TORRENT_ASSERT(m_storage);
TORRENT_ASSERT(m_storage->refcount() > 0);
TORRENT_ASSERT(m_picker.get());
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < m_torrent_file->num_pieces());
if (m_ses.m_alerts.should_post<hash_failed_alert>())
m_ses.m_alerts.post_alert(hash_failed_alert(get_handle(), index));
// increase the total amount of failed bytes
add_failed_bytes(m_torrent_file->piece_size(index));
std::vector<void*> downloaders;
m_picker->get_downloaders(downloaders, index);
// decrease the trust point of all peers that sent
// parts of this piece.
// first, build a set of all peers that participated
std::set<void*> peers;
std::copy(downloaders.begin(), downloaders.end(), std::inserter(peers, peers.begin()));
#ifdef TORRENT_DEBUG
for (std::vector<void*>::iterator i = downloaders.begin()
, end(downloaders.end()); i != end; ++i)
{
policy::peer* p = (policy::peer*)*i;
if (p && p->connection)
{
p->connection->piece_failed = true;
}
}
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
#ifndef BOOST_NO_EXCEPTIONS
try {
#endif
(*i)->on_piece_failed(index);
#ifndef BOOST_NO_EXCEPTIONS
} catch (std::exception&) {}
#endif
}
#endif
for (std::set<void*>::iterator i = peers.begin()
, end(peers.end()); i != end; ++i)
{
policy::peer* p = static_cast<policy::peer*>(*i);
if (p == 0) continue;
if (p->connection) p->connection->received_invalid_data(index);
// either, we have received too many failed hashes
// or this was the only peer that sent us this piece.
if (p->trust_points <= -7
|| peers.size() == 1)
{
// we don't trust this peer anymore
// ban it.
if (m_ses.m_alerts.should_post<peer_ban_alert>())
{
peer_id pid(0);
if (p->connection) pid = p->connection->pid();
m_ses.m_alerts.post_alert(peer_ban_alert(
get_handle(), p->ip(), pid));
}
// mark the peer as banned
m_policy.ban_peer(p);
if (p->connection)
{
#ifdef TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " *** BANNING PEER [ " << p->ip()
<< " ] 'too many corrupt pieces'\n";
#endif
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
(*p->connection->m_logger) << "*** BANNING PEER [ " << p->ip()
<< " ] 'too many corrupt pieces'\n";
#endif
p->connection->disconnect(errors::too_many_corrupt_pieces);
}
}
}
// we have to let the piece_picker know that
// this piece failed the check as it can restore it
// and mark it as being interesting for download
m_picker->restore_piece(index);
restore_piece_state(index);
TORRENT_ASSERT(m_storage);
TORRENT_ASSERT(m_picker->have_piece(index) == false);
#ifdef TORRENT_DEBUG
for (std::vector<void*>::iterator i = downloaders.begin()
, end(downloaders.end()); i != end; ++i)
{
policy::peer* p = (policy::peer*)*i;
if (p && p->connection)
{
p->connection->piece_failed = false;
}
}
#endif
}
void torrent::restore_piece_state(int index)
{
TORRENT_ASSERT(has_picker());
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
peer_connection* p = *i;
std::vector<pending_block> const& dq = p->download_queue();
std::vector<pending_block> const& rq = p->request_queue();
for (std::vector<pending_block>::const_iterator k = dq.begin()
, end(dq.end()); k != end; ++k)
{
if (k->block.piece_index != index) continue;
m_picker->mark_as_downloading(k->block, p->peer_info_struct()
, (piece_picker::piece_state_t)p->peer_speed());
}
for (std::vector<pending_block>::const_iterator k = rq.begin()
, end(rq.end()); k != end; ++k)
{
if (k->block.piece_index != index) continue;
m_picker->mark_as_downloading(k->block, p->peer_info_struct()
, (piece_picker::piece_state_t)p->peer_speed());
}
}
}
void torrent::abort()
{
INVARIANT_CHECK;
if (m_abort) return;
m_abort = true;
// if the torrent is paused, it doesn't need
// to announce with even=stopped again.
if (!is_paused())
{
stop_announcing();
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
(*(*i)->m_logger) << time_now_string() << " *** ABORTING TORRENT\n";
}
#endif
// disconnect all peers and close all
// files belonging to the torrents
disconnect_all(errors::torrent_aborted);
// post a message to the main thread to destruct
// the torrent object from there
if (m_owning_storage.get())
{
m_storage->abort_disk_io();
m_storage->async_release_files(
boost::bind(&torrent::on_torrent_aborted, shared_from_this(), _1, _2));
}
dequeue_torrent_check();
if (m_state == torrent_status::checking_files)
set_state(torrent_status::queued_for_checking);
m_owning_storage = 0;
m_ses.m_host_resolver.cancel();
}
void torrent::super_seeding(bool on)
{
if (on == m_super_seeding) return;
// don't turn on super seeding if we're not a seed
TORRENT_ASSERT(!on || is_seed() || !m_files_checked);
if (on && !is_seed() && m_files_checked) return;
m_super_seeding = on;
if (m_super_seeding) return;
// disable super seeding for all peers
for (peer_iterator i = begin(); i != end(); ++i)
{
(*i)->superseed_piece(-1);
}
}
int torrent::get_piece_to_super_seed(bitfield const& bits)
{
// return a piece with low availability that is not in
// the bitfield and that is not currently being super
// seeded by any peer
TORRENT_ASSERT(m_super_seeding);
// do a linear search from the first piece
int min_availability = 9999;
std::vector<int> avail_vec;
for (int i = 0; i < m_torrent_file->num_pieces(); ++i)
{
if (bits[i]) continue;
int availability = 0;
for (const_peer_iterator j = begin(); j != end(); ++j)
{
if ((*j)->superseed_piece() == i)
{
// avoid superseeding the same piece to more than one
// peer if we can avoid it. Do this by artificially
// increase the availability
availability = 999;
break;
}
if ((*j)->has_piece(i)) ++availability;
}
if (availability > min_availability) continue;
if (availability == min_availability)
{
avail_vec.push_back(i);
continue;
}
TORRENT_ASSERT(availability < min_availability);
min_availability = availability;
avail_vec.clear();
avail_vec.push_back(i);
}
if (min_availability > 1)
{
// if the minimum availability is 2 or more,
// we shouldn't be super seeding any more
super_seeding(false);
return -1;
}
return avail_vec[rand() % avail_vec.size()];
}
void torrent::on_files_deleted(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
if (ret != 0)
{
if (alerts().should_post<torrent_delete_failed_alert>())
alerts().post_alert(torrent_delete_failed_alert(get_handle(), j.error));
}
else
{
if (alerts().should_post<torrent_deleted_alert>())
alerts().post_alert(torrent_deleted_alert(get_handle(), m_torrent_file->info_hash()));
}
}
void torrent::on_files_released(int ret, disk_io_job const& j)
{
/*
mutex::scoped_lock l(m_ses.m_mutex);
if (alerts().should_post<torrent_paused_alert>())
{
alerts().post_alert(torrent_paused_alert(get_handle()));
}
*/
}
void torrent::on_torrent_aborted(int ret, disk_io_job const& j)
{
// the torrent should be completely shut down now, and the
// destructor has to be called from the main thread
}
void torrent::on_save_resume_data(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
if (!j.resume_data)
{
alerts().post_alert(save_resume_data_failed_alert(get_handle(), j.error));
}
else
{
write_resume_data(*j.resume_data);
alerts().post_alert(save_resume_data_alert(j.resume_data
, get_handle()));
}
}
void torrent::on_file_renamed(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
if (ret == 0)
{
if (alerts().should_post<file_renamed_alert>())
alerts().post_alert(file_renamed_alert(get_handle(), j.str, j.piece));
m_torrent_file->rename_file(j.piece, j.str);
}
else
{
if (alerts().should_post<file_rename_failed_alert>())
alerts().post_alert(file_rename_failed_alert(get_handle()
, j.piece, j.error));
}
}
void torrent::on_torrent_paused(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
if (alerts().should_post<torrent_paused_alert>())
alerts().post_alert(torrent_paused_alert(get_handle()));
}
std::string torrent::tracker_login() const
{
if (m_username.empty() && m_password.empty()) return "";
return m_username + ":" + m_password;
}
void torrent::set_piece_deadline(int piece, int t, int flags)
{
ptime deadline = time_now() + milliseconds(t);
if (is_seed() || m_picker->have_piece(piece))
{
if (flags & torrent_handle::alert_when_available)
read_piece(piece);
return;
}
for (std::list<time_critical_piece>::iterator i = m_time_critical_pieces.begin()
, end(m_time_critical_pieces.end()); i != end; ++i)
{
if (i->piece != piece) continue;
i->deadline = deadline;
i->flags = flags;
// resort i since deadline might have changed
while (boost::next(i) != m_time_critical_pieces.end() && i->deadline > boost::next(i)->deadline)
{
std::iter_swap(i, boost::next(i));
++i;
}
while (i != m_time_critical_pieces.begin() && i->deadline < boost::prior(i)->deadline)
{
std::iter_swap(i, boost::next(i));
--i;
}
return;
}
time_critical_piece p;
p.first_requested = min_time();
p.last_requested = min_time();
p.flags = flags;
p.deadline = deadline;
p.peers = 0;
p.piece = piece;
std::list<time_critical_piece>::iterator i = std::upper_bound(m_time_critical_pieces.begin()
, m_time_critical_pieces.end(), p);
m_time_critical_pieces.insert(i, p);
}
void torrent::remove_time_critical_piece(int piece, bool finished)
{
for (std::list<time_critical_piece>::iterator i = m_time_critical_pieces.begin()
, end(m_time_critical_pieces.end()); i != end; ++i)
{
if (i->piece != piece) continue;
if (finished)
{
if (i->flags & torrent_handle::alert_when_available)
{
read_piece(i->piece);
}
// update the average download time and average
// download time deviation
int dl_time = total_milliseconds(time_now() - i->first_requested);
if (m_average_piece_time == 0)
{
m_average_piece_time = dl_time;
}
else
{
int diff = abs(int(dl_time - m_average_piece_time));
if (m_piece_time_deviation == 0) m_piece_time_deviation = diff;
else m_piece_time_deviation = (m_piece_time_deviation * 6 + diff * 4) / 10;
m_average_piece_time = (m_average_piece_time * 6 + dl_time * 4) / 10;
}
}
m_time_critical_pieces.erase(i);
return;
}
}
// remove time critical pieces where priority is 0
void torrent::remove_time_critical_pieces(std::vector<int> const& priority)
{
for (std::list<time_critical_piece>::iterator i = m_time_critical_pieces.begin();
i != m_time_critical_pieces.end();)
{
if (priority[i->piece] == 0)
{
i = m_time_critical_pieces.erase(i);
continue;
}
++i;
}
}
void torrent::piece_availability(std::vector<int>& avail) const
{
INVARIANT_CHECK;
TORRENT_ASSERT(valid_metadata());
if (is_seed())
{
avail.clear();
return;
}
m_picker->get_availability(avail);
}
void torrent::set_piece_priority(int index, int priority)
{
// INVARIANT_CHECK;
TORRENT_ASSERT(valid_metadata());
if (is_seed()) return;
// this call is only valid on torrents with metadata
TORRENT_ASSERT(m_picker.get());
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < m_torrent_file->num_pieces());
bool was_finished = is_finished();
bool filter_updated = m_picker->set_piece_priority(index, priority);
TORRENT_ASSERT(num_have() >= m_picker->num_have_filtered());
if (filter_updated)
{
update_peer_interest(was_finished);
if (priority == 0) remove_time_critical_piece(index);
}
}
int torrent::piece_priority(int index) const
{
// INVARIANT_CHECK;
TORRENT_ASSERT(valid_metadata());
if (is_seed()) return 1;
// this call is only valid on torrents with metadata
TORRENT_ASSERT(m_picker.get());
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < m_torrent_file->num_pieces());
return m_picker->piece_priority(index);
}
void torrent::prioritize_pieces(std::vector<int> const& pieces)
{
INVARIANT_CHECK;
// this call is only valid on torrents with metadata
TORRENT_ASSERT(valid_metadata());
if (is_seed()) return;
TORRENT_ASSERT(m_picker.get());
int index = 0;
bool filter_updated = false;
bool was_finished = is_finished();
for (std::vector<int>::const_iterator i = pieces.begin()
, end(pieces.end()); i != end; ++i, ++index)
{
TORRENT_ASSERT(*i >= 0);
TORRENT_ASSERT(*i <= 7);
filter_updated |= m_picker->set_piece_priority(index, *i);
TORRENT_ASSERT(num_have() >= m_picker->num_have_filtered());
}
if (filter_updated)
{
update_peer_interest(was_finished);
remove_time_critical_pieces(pieces);
}
}
void torrent::piece_priorities(std::vector<int>& pieces) const
{
INVARIANT_CHECK;
// this call is only valid on torrents with metadata
TORRENT_ASSERT(valid_metadata());
if (is_seed())
{
pieces.clear();
pieces.resize(m_torrent_file->num_pieces(), 1);
return;
}
TORRENT_ASSERT(m_picker.get());
m_picker->piece_priorities(pieces);
}
namespace
{
void set_if_greater(int& piece_prio, int file_prio)
{
if (file_prio > piece_prio) piece_prio = file_prio;
}
}
void torrent::prioritize_files(std::vector<int> const& files)
{
INVARIANT_CHECK;
// this call is only valid on torrents with metadata
if (!valid_metadata() || is_seed()) return;
// the bitmask need to have exactly one bit for every file
// in the torrent
TORRENT_ASSERT(int(files.size()) == m_torrent_file->num_files());
if (m_torrent_file->num_pieces() == 0) return;
std::copy(files.begin(), files.end(), m_file_priority.begin());
update_piece_priorities();
}
void torrent::set_file_priority(int index, int prio)
{
INVARIANT_CHECK;
// this call is only valid on torrents with metadata
if (!valid_metadata() || is_seed()) return;
TORRENT_ASSERT(index < m_torrent_file->num_files());
TORRENT_ASSERT(index >= 0);
if (m_file_priority[index] == prio) return;
m_file_priority[index] = prio;
update_piece_priorities();
}
int torrent::file_priority(int index) const
{
// this call is only valid on torrents with metadata
if (!valid_metadata()) return 1;
TORRENT_ASSERT(index < m_torrent_file->num_files());
TORRENT_ASSERT(index >= 0);
return m_file_priority[index];
}
void torrent::file_priorities(std::vector<int>& files) const
{
INVARIANT_CHECK;
files.resize(m_file_priority.size());
std::copy(m_file_priority.begin(), m_file_priority.end(), files.begin());
}
void torrent::update_piece_priorities()
{
INVARIANT_CHECK;
if (m_torrent_file->num_pieces() == 0) return;
size_type position = 0;
int piece_length = m_torrent_file->piece_length();
// initialize the piece priorities to 0, then only allow
// setting higher priorities
std::vector<int> pieces(m_torrent_file->num_pieces(), 0);
for (int i = 0; i < int(m_file_priority.size()); ++i)
{
size_type start = position;
size_type size = m_torrent_file->files().at(i).size;
if (size == 0) continue;
position += size;
if (m_file_priority[i] == 0) continue;
// mark all pieces of the file with this file's priority
// but only if the priority is higher than the pieces
// already set (to avoid problems with overlapping pieces)
int start_piece = int(start / piece_length);
int last_piece = int((position - 1) / piece_length);
TORRENT_ASSERT(last_piece < int(pieces.size()));
// if one piece spans several files, we might
// come here several times with the same start_piece, end_piece
std::for_each(pieces.begin() + start_piece
, pieces.begin() + last_piece + 1
, bind(&set_if_greater, _1, m_file_priority[i]));
}
prioritize_pieces(pieces);
}
// this is called when piece priorities have been updated
// updates the interested flag in peers
void torrent::update_peer_interest(bool was_finished)
{
for (peer_iterator i = begin(); i != end();)
{
peer_connection* p = *i;
// update_interest may disconnect the peer and
// invalidate the iterator
++i;
p->update_interest();
}
// the torrent just became finished
if (is_finished() && !was_finished)
{
finished();
}
else if (!is_finished() && was_finished)
{
// if we used to be finished, but we aren't anymore
// we may need to connect to peers again
resume_download();
}
}
void torrent::filter_piece(int index, bool filter)
{
INVARIANT_CHECK;
TORRENT_ASSERT(valid_metadata());
if (is_seed()) return;
// this call is only valid on torrents with metadata
TORRENT_ASSERT(m_picker.get());
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < m_torrent_file->num_pieces());
bool was_finished = is_finished();
m_picker->set_piece_priority(index, filter ? 1 : 0);
update_peer_interest(was_finished);
}
void torrent::filter_pieces(std::vector<bool> const& bitmask)
{
INVARIANT_CHECK;
// this call is only valid on torrents with metadata
TORRENT_ASSERT(valid_metadata());
if (is_seed()) return;
TORRENT_ASSERT(m_picker.get());
bool was_finished = is_finished();
int index = 0;
for (std::vector<bool>::const_iterator i = bitmask.begin()
, end(bitmask.end()); i != end; ++i, ++index)
{
if ((m_picker->piece_priority(index) == 0) == *i) continue;
if (*i)
m_picker->set_piece_priority(index, 0);
else
m_picker->set_piece_priority(index, 1);
}
update_peer_interest(was_finished);
}
bool torrent::is_piece_filtered(int index) const
{
// this call is only valid on torrents with metadata
TORRENT_ASSERT(valid_metadata());
if (is_seed()) return false;
TORRENT_ASSERT(m_picker.get());
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < m_torrent_file->num_pieces());
return m_picker->piece_priority(index) == 0;
}
void torrent::filtered_pieces(std::vector<bool>& bitmask) const
{
INVARIANT_CHECK;
// this call is only valid on torrents with metadata
TORRENT_ASSERT(valid_metadata());
if (is_seed())
{
bitmask.clear();
bitmask.resize(m_torrent_file->num_pieces(), false);
return;
}
TORRENT_ASSERT(m_picker.get());
m_picker->filtered_pieces(bitmask);
}
void torrent::filter_files(std::vector<bool> const& bitmask)
{
INVARIANT_CHECK;
// this call is only valid on torrents with metadata
if (!valid_metadata() || is_seed()) return;
// the bitmask need to have exactly one bit for every file
// in the torrent
TORRENT_ASSERT((int)bitmask.size() == m_torrent_file->num_files());
size_type position = 0;
if (m_torrent_file->num_pieces())
{
int piece_length = m_torrent_file->piece_length();
// mark all pieces as filtered, then clear the bits for files
// that should be downloaded
std::vector<bool> piece_filter(m_torrent_file->num_pieces(), true);
for (int i = 0; i < (int)bitmask.size(); ++i)
{
size_type start = position;
position += m_torrent_file->files().at(i).size;
// is the file selected for download?
if (!bitmask[i])
{
// mark all pieces of the file as downloadable
int start_piece = int(start / piece_length);
int last_piece = int(position / piece_length);
// if one piece spans several files, we might
// come here several times with the same start_piece, end_piece
std::fill(piece_filter.begin() + start_piece, piece_filter.begin()
+ last_piece + 1, false);
}
}
filter_pieces(piece_filter);
}
}
void torrent::replace_trackers(std::vector<announce_entry> const& urls)
{
m_trackers.clear();
std::remove_copy_if(urls.begin(), urls.end(), back_inserter(m_trackers)
, boost::bind(&std::string::empty, boost::bind(&announce_entry::url, _1)));
m_last_working_tracker = -1;
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
if (i->source == 0) i->source = announce_entry::source_client;
if (settings().prefer_udp_trackers)
prioritize_udp_trackers();
if (!m_trackers.empty()) start_announcing();
else stop_announcing();
}
void torrent::prioritize_udp_trackers()
{
// look for udp-trackers
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
{
if (i->url.substr(0, 6) != "udp://") continue;
// now, look for trackers with the same hostname
// that is has higher priority than this one
// if we find one, swap with the udp-tracker
error_code ec;
std::string udp_hostname;
using boost::tuples::ignore;
boost::tie(ignore, ignore, udp_hostname, ignore, ignore)
= parse_url_components(i->url, ec);
for (std::vector<announce_entry>::iterator j = m_trackers.begin();
j != i; ++j)
{
std::string hostname;
boost::tie(ignore, ignore, hostname, ignore, ignore)
= parse_url_components(j->url, ec);
if (hostname != udp_hostname) continue;
if (j->url.substr(0, 6) == "udp://") continue;
using std::swap;
using std::iter_swap;
swap(i->tier, j->tier);
iter_swap(i, j);
break;
}
}
}
void torrent::add_tracker(announce_entry const& url)
{
std::vector<announce_entry>::iterator k = std::find_if(m_trackers.begin()
, m_trackers.end(), boost::bind(&announce_entry::url, _1) == url.url);
if (k != m_trackers.end())
{
k->source |= url.source;
return;
}
k = std::upper_bound(m_trackers.begin(), m_trackers.end(), url
, boost::bind(&announce_entry::tier, _1) < boost::bind(&announce_entry::tier, _2));
if (k - m_trackers.begin() < m_last_working_tracker) ++m_last_working_tracker;
k = m_trackers.insert(k, url);
if (k->source == 0) k->source = announce_entry::source_client;
if (!m_trackers.empty()) start_announcing();
}
bool torrent::choke_peer(peer_connection& c)
{
INVARIANT_CHECK;
TORRENT_ASSERT(!c.is_choked());
TORRENT_ASSERT(!c.ignore_unchoke_slots());
TORRENT_ASSERT(m_num_uploads > 0);
if (!c.send_choke()) return false;
--m_num_uploads;
return true;
}
bool torrent::unchoke_peer(peer_connection& c)
{
INVARIANT_CHECK;
TORRENT_ASSERT(c.is_choked());
TORRENT_ASSERT(!c.ignore_unchoke_slots());
if (m_num_uploads >= m_max_uploads) return false;
if (!c.send_unchoke()) return false;
++m_num_uploads;
return true;
}
void torrent::cancel_block(piece_block block)
{
INVARIANT_CHECK;
for (peer_iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
{
(*i)->cancel_request(block);
}
}
void torrent::remove_peer(peer_connection* p)
{
// INVARIANT_CHECK;
TORRENT_ASSERT(p != 0);
peer_iterator i = m_connections.find(p);
if (i == m_connections.end())
{
TORRENT_ASSERT(false);
return;
}
if (ready_for_connections())
{
TORRENT_ASSERT(p->associated_torrent().lock().get() == this);
if (p->is_seed())
{
if (m_picker.get())
{
m_picker->dec_refcount_all();
}
}
else
{
if (m_picker.get())
{
bitfield const& pieces = p->get_bitfield();
TORRENT_ASSERT(pieces.count() < int(pieces.size()));
m_picker->dec_refcount(pieces);
}
}
}
if (!p->is_choked() && !p->ignore_unchoke_slots())
{
--m_num_uploads;
m_ses.m_unchoke_time_scaler = 0;
}
policy::peer* pp = p->peer_info_struct();
if (pp)
{
if (pp->optimistically_unchoked)
m_ses.m_optimistic_unchoke_time_scaler = 0;
// if the share ratio is 0 (infinite), the
// m_available_free_upload isn't used,
// because it isn't necessary.
if (ratio() != 0.f)
{
TORRENT_ASSERT(p->associated_torrent().lock().get() == this);
TORRENT_ASSERT(p->share_diff() < (std::numeric_limits<size_type>::max)());
m_available_free_upload += p->share_diff();
}
TORRENT_ASSERT(pp->prev_amount_upload == 0);
TORRENT_ASSERT(pp->prev_amount_download == 0);
pp->prev_amount_download += p->statistics().total_payload_download();
pp->prev_amount_upload += p->statistics().total_payload_upload();
}
m_policy.connection_closed(*p, m_ses.session_time());
p->set_peer_info(0);
TORRENT_ASSERT(i != m_connections.end());
m_connections.erase(i);
}
void torrent::connect_to_url_seed(std::list<web_seed_entry>::iterator web)
{
INVARIANT_CHECK;
TORRENT_ASSERT(!web->resolving);
if (web->resolving) return;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " resolving web seed: " << web->url << "\n";
#endif
std::string protocol;
std::string auth;
std::string hostname;
int port;
std::string path;
error_code ec;
boost::tie(protocol, auth, hostname, port, path)
= parse_url_components(web->url, ec);
if (ec)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " failed to parse web seed url: " << ec.message() << "\n";
#endif
// never try it again
m_web_seeds.erase(web);
return;
}
#ifdef TORRENT_USE_OPENSSL
if (protocol != "http" && protocol != "https")
#else
if (protocol != "http")
#endif
{
if (m_ses.m_alerts.should_post<url_seed_alert>())
{
m_ses.m_alerts.post_alert(
url_seed_alert(get_handle(), web->url, errors::unsupported_url_protocol));
}
// never try it again
m_web_seeds.erase(web);
return;
}
if (hostname.empty())
{
if (m_ses.m_alerts.should_post<url_seed_alert>())
{
m_ses.m_alerts.post_alert(
url_seed_alert(get_handle(), web->url, errors::invalid_hostname));
}
// never try it again
m_web_seeds.erase(web);
return;
}
if (port == 0)
{
if (m_ses.m_alerts.should_post<url_seed_alert>())
{
m_ses.m_alerts.post_alert(
url_seed_alert(get_handle(), web->url, errors::invalid_port));
}
// never try it again
m_web_seeds.erase(web);
return;
}
if (web->endpoint.port() != 0)
{
// TODO: we have already resolved this URL, just connect
}
web->resolving = true;
proxy_settings const& ps = m_ses.web_seed_proxy();
if (ps.type == proxy_settings::http
|| ps.type == proxy_settings::http_pw)
{
// use proxy
tcp::resolver::query q(ps.hostname, to_string(ps.port).elems);
m_ses.m_host_resolver.async_resolve(q,
bind(&torrent::on_proxy_name_lookup, shared_from_this(), _1, _2, web));
}
else
{
if (m_ses.m_port_filter.access(port) & port_filter::blocked)
{
if (m_ses.m_alerts.should_post<url_seed_alert>())
{
m_ses.m_alerts.post_alert(
url_seed_alert(get_handle(), web->url, errors::port_blocked));
}
// never try it again
m_web_seeds.erase(web);
return;
}
tcp::resolver::query q(hostname, to_string(port).elems);
m_ses.m_host_resolver.async_resolve(q,
bind(&torrent::on_name_lookup, shared_from_this(), _1, _2, web
, tcp::endpoint()));
}
}
void torrent::on_proxy_name_lookup(error_code const& e, tcp::resolver::iterator host
, std::list<web_seed_entry>::iterator web)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " completed resolve proxy hostname for: " << web->url << "\n";
if (e)
*m_ses.m_logger << time_now_string() << " on_proxy_name_lookup: " << e.message() << "\n";
#endif
if (m_abort) return;
if (e || host == tcp::resolver::iterator())
{
if (m_ses.m_alerts.should_post<url_seed_alert>())
{
m_ses.m_alerts.post_alert(
url_seed_alert(get_handle(), web->url, e));
}
// the name lookup failed for the http host. Don't try
// this host again
m_web_seeds.erase(web);
return;
}
if (m_ses.is_aborted()) return;
tcp::endpoint a(host->endpoint());
using boost::tuples::ignore;
std::string hostname;
int port;
error_code ec;
boost::tie(ignore, ignore, hostname, port, ignore)
= parse_url_components(web->url, ec);
if (ec)
{
if (m_ses.m_alerts.should_post<url_seed_alert>())
{
m_ses.m_alerts.post_alert(
url_seed_alert(get_handle(), web->url, ec));
}
m_web_seeds.erase(web);
return;
}
if (m_ses.m_ip_filter.access(a.address()) & ip_filter::blocked)
{
if (m_ses.m_alerts.should_post<peer_blocked_alert>())
m_ses.m_alerts.post_alert(peer_blocked_alert(get_handle(), a.address()));
return;
}
tcp::resolver::query q(hostname, to_string(port).elems);
m_ses.m_host_resolver.async_resolve(q,
bind(&torrent::on_name_lookup, shared_from_this(), _1, _2, web, a));
}
void torrent::on_name_lookup(error_code const& e, tcp::resolver::iterator host
, std::list<web_seed_entry>::iterator web, tcp::endpoint proxy)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " completed resolve: " << web->url << "\n";
#endif
web->resolving = false;
if (m_abort) return;
if (e || host == tcp::resolver::iterator())
{
if (m_ses.m_alerts.should_post<url_seed_alert>())
m_ses.m_alerts.post_alert(url_seed_alert(get_handle(), web->url, e));
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << " ** HOSTNAME LOOKUP FAILED!**: " << web->url
<< " " << e.message() << "\n";
#endif
// unavailable, retry in 30 minutes
web->retry = time_now() + minutes(30);
return;
}
tcp::endpoint a(host->endpoint());
if (m_ses.m_ip_filter.access(a.address()) & ip_filter::blocked)
{
if (m_ses.m_alerts.should_post<peer_blocked_alert>())
m_ses.m_alerts.post_alert(peer_blocked_alert(get_handle(), a.address()));
return;
}
web->endpoint = a;
if (is_paused()) return;
if (m_ses.is_aborted()) return;
boost::shared_ptr<socket_type> s(new (std::nothrow) socket_type(m_ses.m_io_service));
if (!s) return;
bool ret = instantiate_connection(m_ses.m_io_service, m_ses.web_seed_proxy(), *s);
(void)ret;
TORRENT_ASSERT(ret);
if (m_ses.web_seed_proxy().type == proxy_settings::http
|| m_ses.web_seed_proxy().type == proxy_settings::http_pw)
{
// the web seed connection will talk immediately to
// the proxy, without requiring CONNECT support
s->get<http_stream>()->set_no_connect(true);
}
boost::intrusive_ptr<peer_connection> c;
if (web->type == web_seed_entry::url_seed)
{
c = new (std::nothrow) web_peer_connection(
m_ses, shared_from_this(), s, a, web->url, 0);
}
else if (web->type == web_seed_entry::http_seed)
{
c = new (std::nothrow) http_seed_connection(
m_ses, shared_from_this(), s, a, web->url, 0);
}
if (!c) return;
#ifdef TORRENT_DEBUG
c->m_in_constructor = false;
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
boost::shared_ptr<peer_plugin>
pp((*i)->new_connection(c.get()));
if (pp) c->add_extension(pp);
}
#endif
#ifndef BOOST_NO_EXCEPTIONS
try
{
#endif
// add the newly connected peer to this torrent's peer list
m_connections.insert(boost::get_pointer(c));
m_ses.m_connections.insert(c);
web->connection = c.get();
c->start();
m_ses.m_half_open.enqueue(
bind(&peer_connection::on_connect, c, _1)
, bind(&peer_connection::on_timeout, c)
, seconds(settings().peer_connect_timeout));
#ifndef BOOST_NO_EXCEPTIONS
}
catch (std::exception& e)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << " ** HOSTNAME LOOKUP FAILED!**: " << e.what() << "\n";
#endif
c->disconnect(errors::no_error, 1);
}
#endif
}
#ifndef TORRENT_DISABLE_RESOLVE_COUNTRIES
namespace
{
unsigned long swap_bytes(unsigned long a)
{
return (a >> 24) | ((a & 0xff0000) >> 8) | ((a & 0xff00) << 8) | ((a & 0xff) << 24);
}
}
void torrent::resolve_peer_country(boost::intrusive_ptr<peer_connection> const& p) const
{
if (m_resolving_country
|| is_local(p->remote().address())
|| p->has_country()
|| p->is_connecting()
|| p->is_queued()
|| p->in_handshake()
|| p->remote().address().is_v6()) return;
asio::ip::address_v4 reversed(swap_bytes(p->remote().address().to_v4().to_ulong()));
error_code ec;
tcp::resolver::query q(reversed.to_string(ec) + ".zz.countries.nerd.dk", "0");
if (ec)
{
p->set_country("!!");
return;
}
m_resolving_country = true;
m_ses.m_host_resolver.async_resolve(q,
bind(&torrent::on_country_lookup, shared_from_this(), _1, _2, p));
}
namespace
{
struct country_entry
{
int code;
char const* name;
};
}
void torrent::on_country_lookup(error_code const& error, tcp::resolver::iterator i
, intrusive_ptr<peer_connection> p) const
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
m_resolving_country = false;
if (m_abort) return;
// must be ordered in increasing order
static const country_entry country_map[] =
{
{ 4, "AF"}, { 8, "AL"}, { 10, "AQ"}, { 12, "DZ"}, { 16, "AS"}
, { 20, "AD"}, { 24, "AO"}, { 28, "AG"}, { 31, "AZ"}, { 32, "AR"}
, { 36, "AU"}, { 40, "AT"}, { 44, "BS"}, { 48, "BH"}, { 50, "BD"}
, { 51, "AM"}, { 52, "BB"}, { 56, "BE"}, { 60, "BM"}, { 64, "BT"}
, { 68, "BO"}, { 70, "BA"}, { 72, "BW"}, { 74, "BV"}, { 76, "BR"}
, { 84, "BZ"}, { 86, "IO"}, { 90, "SB"}, { 92, "VG"}, { 96, "BN"}
, {100, "BG"}, {104, "MM"}, {108, "BI"}, {112, "BY"}, {116, "KH"}
, {120, "CM"}, {124, "CA"}, {132, "CV"}, {136, "KY"}, {140, "CF"}
, {144, "LK"}, {148, "TD"}, {152, "CL"}, {156, "CN"}, {158, "TW"}
, {162, "CX"}, {166, "CC"}, {170, "CO"}, {174, "KM"}, {175, "YT"}
, {178, "CG"}, {180, "CD"}, {184, "CK"}, {188, "CR"}, {191, "HR"}
, {192, "CU"}, {203, "CZ"}, {204, "BJ"}, {208, "DK"}, {212, "DM"}
, {214, "DO"}, {218, "EC"}, {222, "SV"}, {226, "GQ"}, {231, "ET"}
, {232, "ER"}, {233, "EE"}, {234, "FO"}, {238, "FK"}, {239, "GS"}
, {242, "FJ"}, {246, "FI"}, {248, "AX"}, {250, "FR"}, {254, "GF"}
, {258, "PF"}, {260, "TF"}, {262, "DJ"}, {266, "GA"}, {268, "GE"}
, {270, "GM"}, {275, "PS"}, {276, "DE"}, {288, "GH"}, {292, "GI"}
, {296, "KI"}, {300, "GR"}, {304, "GL"}, {308, "GD"}, {312, "GP"}
, {316, "GU"}, {320, "GT"}, {324, "GN"}, {328, "GY"}, {332, "HT"}
, {334, "HM"}, {336, "VA"}, {340, "HN"}, {344, "HK"}, {348, "HU"}
, {352, "IS"}, {356, "IN"}, {360, "ID"}, {364, "IR"}, {368, "IQ"}
, {372, "IE"}, {376, "IL"}, {380, "IT"}, {384, "CI"}, {388, "JM"}
, {392, "JP"}, {398, "KZ"}, {400, "JO"}, {404, "KE"}, {408, "KP"}
, {410, "KR"}, {414, "KW"}, {417, "KG"}, {418, "LA"}, {422, "LB"}
, {426, "LS"}, {428, "LV"}, {430, "LR"}, {434, "LY"}, {438, "LI"}
, {440, "LT"}, {442, "LU"}, {446, "MO"}, {450, "MG"}, {454, "MW"}
, {458, "MY"}, {462, "MV"}, {466, "ML"}, {470, "MT"}, {474, "MQ"}
, {478, "MR"}, {480, "MU"}, {484, "MX"}, {492, "MC"}, {496, "MN"}
, {498, "MD"}, {500, "MS"}, {504, "MA"}, {508, "MZ"}, {512, "OM"}
, {516, "NA"}, {520, "NR"}, {524, "NP"}, {528, "NL"}, {530, "AN"}
, {533, "AW"}, {540, "NC"}, {548, "VU"}, {554, "NZ"}, {558, "NI"}
, {562, "NE"}, {566, "NG"}, {570, "NU"}, {574, "NF"}, {578, "NO"}
, {580, "MP"}, {581, "UM"}, {583, "FM"}, {584, "MH"}, {585, "PW"}
, {586, "PK"}, {591, "PA"}, {598, "PG"}, {600, "PY"}, {604, "PE"}
, {608, "PH"}, {612, "PN"}, {616, "PL"}, {620, "PT"}, {624, "GW"}
, {626, "TL"}, {630, "PR"}, {634, "QA"}, {634, "QA"}, {638, "RE"}
, {642, "RO"}, {643, "RU"}, {646, "RW"}, {654, "SH"}, {659, "KN"}
, {660, "AI"}, {662, "LC"}, {666, "PM"}, {670, "VC"}, {674, "SM"}
, {678, "ST"}, {682, "SA"}, {686, "SN"}, {690, "SC"}, {694, "SL"}
, {702, "SG"}, {703, "SK"}, {704, "VN"}, {705, "SI"}, {706, "SO"}
, {710, "ZA"}, {716, "ZW"}, {724, "ES"}, {732, "EH"}, {736, "SD"}
, {740, "SR"}, {744, "SJ"}, {748, "SZ"}, {752, "SE"}, {756, "CH"}
, {760, "SY"}, {762, "TJ"}, {764, "TH"}, {768, "TG"}, {772, "TK"}
, {776, "TO"}, {780, "TT"}, {784, "AE"}, {788, "TN"}, {792, "TR"}
, {795, "TM"}, {796, "TC"}, {798, "TV"}, {800, "UG"}, {804, "UA"}
, {807, "MK"}, {818, "EG"}, {826, "GB"}, {834, "TZ"}, {840, "US"}
, {850, "VI"}, {854, "BF"}, {858, "UY"}, {860, "UZ"}, {862, "VE"}
, {876, "WF"}, {882, "WS"}, {887, "YE"}, {891, "CS"}, {894, "ZM"}
};
if (error || i == tcp::resolver::iterator())
{
// this is used to indicate that we shouldn't
// try to resolve it again
p->set_country("--");
return;
}
while (i != tcp::resolver::iterator()
&& !i->endpoint().address().is_v4()) ++i;
if (i != tcp::resolver::iterator())
{
// country is an ISO 3166 country code
int country = i->endpoint().address().to_v4().to_ulong() & 0xffff;
// look up the country code in the map
const int size = sizeof(country_map)/sizeof(country_map[0]);
country_entry tmp = {country, ""};
country_entry const* i =
std::lower_bound(country_map, country_map + size, tmp
, bind(&country_entry::code, _1) < bind(&country_entry::code, _2));
if (i == country_map + size
|| i->code != country)
{
// unknown country!
p->set_country("!!");
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
(*m_ses.m_logger) << "IP " << p->remote().address() << " was mapped to unknown country: " << country << "\n";
#endif
return;
}
p->set_country(i->name);
}
}
#endif
void torrent::read_resume_data(lazy_entry const& rd)
{
m_total_uploaded = rd.dict_find_int_value("total_uploaded");
m_total_downloaded = rd.dict_find_int_value("total_downloaded");
m_active_time = rd.dict_find_int_value("active_time");
m_finished_time = rd.dict_find_int_value("finished_time");
m_seeding_time = rd.dict_find_int_value("seeding_time");
m_complete = rd.dict_find_int_value("num_seeds", -1);
m_incomplete = rd.dict_find_int_value("num_downloaders", -1);
set_upload_limit(rd.dict_find_int_value("upload_rate_limit", -1));
set_download_limit(rd.dict_find_int_value("download_rate_limit", -1));
set_max_connections(rd.dict_find_int_value("max_connections", -1));
set_max_uploads(rd.dict_find_int_value("max_uploads", -1));
m_seed_mode = rd.dict_find_int_value("seed_mode", 0) && m_torrent_file->is_valid();
if (m_seed_mode) m_verified.resize(m_torrent_file->num_pieces(), false);
super_seeding(rd.dict_find_int_value("super_seeding", 0));
lazy_entry const* file_priority = rd.dict_find_list("file_priority");
if (file_priority && file_priority->list_size()
== m_torrent_file->num_files())
{
for (int i = 0; i < file_priority->list_size(); ++i)
m_file_priority[i] = file_priority->list_int_value_at(i, 1);
update_piece_priorities();
}
lazy_entry const* piece_priority = rd.dict_find_string("piece_priority");
if (piece_priority && piece_priority->string_length()
== m_torrent_file->num_pieces())
{
char const* p = piece_priority->string_ptr();
for (int i = 0; i < piece_priority->string_length(); ++i)
m_picker->set_piece_priority(i, p[i]);
}
if (!m_override_resume_data)
{
int auto_managed_ = rd.dict_find_int_value("auto_managed", -1);
if (auto_managed_ != -1) m_auto_managed = auto_managed_;
}
int sequential_ = rd.dict_find_int_value("sequential_download", -1);
if (sequential_ != -1) set_sequential_download(sequential_);
if (!m_override_resume_data)
{
int paused_ = rd.dict_find_int_value("paused", -1);
if (paused_ != -1) m_paused = paused_;
}
lazy_entry const* trackers = rd.dict_find_list("trackers");
if (trackers)
{
m_trackers.clear();
int tier = 0;
for (int i = 0; i < trackers->list_size(); ++i)
{
lazy_entry const* tier_list = trackers->list_at(i);
if (tier_list == 0 || tier_list->type() != lazy_entry::list_t)
continue;
for (int j = 0; j < tier_list->list_size(); ++j)
{
announce_entry e(tier_list->list_string_value_at(j));
if (std::find_if(m_trackers.begin(), m_trackers.end()
, boost::bind(&announce_entry::url, _1) == e.url) != m_trackers.end())
continue;
e.tier = tier;
m_trackers.push_back(e);
}
++tier;
}
std::sort(m_trackers.begin(), m_trackers.end(), boost::bind(&announce_entry::tier, _1)
< boost::bind(&announce_entry::tier, _2));
if (settings().prefer_udp_trackers)
prioritize_udp_trackers();
}
lazy_entry const* mapped_files = rd.dict_find_list("mapped_files");
if (mapped_files && mapped_files->list_size() == m_torrent_file->num_files())
{
for (int i = 0; i < m_torrent_file->num_files(); ++i)
{
std::string new_filename = mapped_files->list_string_value_at(i);
if (new_filename.empty()) continue;
m_torrent_file->rename_file(i, new_filename);
}
}
lazy_entry const* url_list = rd.dict_find_list("url-list");
if (url_list)
{
for (int i = 0; i < url_list->list_size(); ++i)
{
std::string url = url_list->list_string_value_at(i);
if (url.empty()) continue;
add_web_seed(url, web_seed_entry::url_seed);
}
}
lazy_entry const* httpseeds = rd.dict_find_list("httpseeds");
if (httpseeds)
{
for (int i = 0; i < httpseeds->list_size(); ++i)
{
std::string url = httpseeds->list_string_value_at(i);
if (url.empty()) continue;
add_web_seed(url, web_seed_entry::http_seed);
}
}
if (m_torrent_file->is_merkle_torrent())
{
lazy_entry const* mt = rd.dict_find_string("merkle tree");
if (mt)
{
std::vector<sha1_hash> tree;
tree.resize(m_torrent_file->merkle_tree().size());
std::memcpy(&tree[0], mt->string_ptr()
, (std::min)(mt->string_length(), int(tree.size()) * 20));
if (mt->string_length() < int(tree.size()) * 20)
std::memset(&tree[0] + mt->string_length() / 20, 0
, tree.size() - mt->string_length() / 20);
m_torrent_file->set_merkle_tree(tree);
}
else
{
// TODO: if this is a merkle torrent and we can't
// restore the tree, we need to wipe all the
// bits in the have array, but not necessarily
// we might want to do a full check to see if we have
// all the pieces
TORRENT_ASSERT(false);
}
}
}
void torrent::write_resume_data(entry& ret) const
{
using namespace libtorrent::detail; // for write_*_endpoint()
ret["file-format"] = "libtorrent resume file";
ret["file-version"] = 1;
ret["libtorrent-version"] = LIBTORRENT_VERSION;
ret["total_uploaded"] = m_total_uploaded;
ret["total_downloaded"] = m_total_downloaded;
ret["active_time"] = m_active_time;
ret["finished_time"] = m_finished_time;
ret["seeding_time"] = m_seeding_time;
int seeds = 0;
int downloaders = 0;
if (m_complete >= 0) seeds = m_complete;
else seeds = m_policy.num_seeds();
if (m_incomplete >= 0) downloaders = m_incomplete;
else downloaders = m_policy.num_peers() - m_policy.num_seeds();
ret["num_seeds"] = seeds;
ret["num_downloaders"] = downloaders;
ret["sequential_download"] = m_sequential_download;
ret["seed_mode"] = m_seed_mode;
ret["super_seeding"] = m_super_seeding;
const sha1_hash& info_hash = torrent_file().info_hash();
ret["info-hash"] = std::string((char*)info_hash.begin(), (char*)info_hash.end());
// blocks per piece
int num_blocks_per_piece =
static_cast<int>(torrent_file().piece_length()) / block_size();
ret["blocks per piece"] = num_blocks_per_piece;
if (m_torrent_file->is_merkle_torrent())
{
// we need to save the whole merkle hash tree
// in order to resume
std::string& tree_str = ret["merkle tree"].string();
std::vector<sha1_hash> const& tree = m_torrent_file->merkle_tree();
tree_str.resize(tree.size() * 20);
std::memcpy(&tree_str[0], &tree[0], tree.size() * 20);
}
// if this torrent is a seed, we won't have a piece picker
// and there will be no half-finished pieces.
if (!is_seed())
{
const std::vector<piece_picker::downloading_piece>& q
= m_picker->get_download_queue();
// unfinished pieces
ret["unfinished"] = entry::list_type();
entry::list_type& up = ret["unfinished"].list();
// info for each unfinished piece
for (std::vector<piece_picker::downloading_piece>::const_iterator i
= q.begin(); i != q.end(); ++i)
{
if (i->finished == 0) continue;
entry piece_struct(entry::dictionary_t);
// the unfinished piece's index
piece_struct["piece"] = i->index;
std::string bitmask;
const int num_bitmask_bytes
= (std::max)(num_blocks_per_piece / 8, 1);
for (int j = 0; j < num_bitmask_bytes; ++j)
{
unsigned char v = 0;
int bits = (std::min)(num_blocks_per_piece - j*8, 8);
for (int k = 0; k < bits; ++k)
v |= (i->info[j*8+k].state == piece_picker::block_info::state_finished)
? (1 << k) : 0;
bitmask.append(1, v);
TORRENT_ASSERT(bits == 8 || j == num_bitmask_bytes - 1);
}
piece_struct["bitmask"] = bitmask;
// push the struct onto the unfinished-piece list
up.push_back(piece_struct);
}
}
// save trackers
if (!m_trackers.empty())
{
entry::list_type& tr_list = ret["trackers"].list();
tr_list.push_back(entry::list_type());
int tier = 0;
for (std::vector<announce_entry>::const_iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
{
// don't save trackers we can't trust
// TODO: save the send_stats state instead
if (i->send_stats == false) continue;
if (i->tier == tier)
{
tr_list.back().list().push_back(i->url);
}
else
{
tr_list.push_back(entry::list_t);
tr_list.back().list().push_back(i->url);
tier = i->tier;
}
}
}
// save web seeds
if (!m_web_seeds.empty())
{
entry::list_type& url_list = ret["url-list"].list();
entry::list_type& httpseed_list = ret["httpseeds"].list();
for (std::list<web_seed_entry>::const_iterator i = m_web_seeds.begin()
, end(m_web_seeds.end()); i != end; ++i)
{
if (i->type == web_seed_entry::url_seed)
url_list.push_back(i->url);
else if (i->type == web_seed_entry::http_seed)
httpseed_list.push_back(i->url);
}
}
// write have bitmask
// the pieces string has one byte per piece. Each
// byte is a bitmask representing different properties
// for the piece
// bit 0: set if we have the piece
// bit 1: set if we have verified the piece (in seed mode)
entry::string_type& pieces = ret["pieces"].string();
pieces.resize(m_torrent_file->num_pieces());
if (is_seed())
{
std::memset(&pieces[0], 1, pieces.size());
}
else
{
for (int i = 0, end(pieces.size()); i < end; ++i)
pieces[i] = m_picker->have_piece(i) ? 1 : 0;
}
if (m_seed_mode)
{
TORRENT_ASSERT(m_verified.size() == pieces.size());
for (int i = 0, end(pieces.size()); i < end; ++i)
pieces[i] |= m_verified[i] ? 2 : 0;
}
// write renamed files
if (&m_torrent_file->files() != &m_torrent_file->orig_files())
{
entry::list_type& fl = ret["mapped_files"].list();
for (torrent_info::file_iterator i = m_torrent_file->begin_files()
, end(m_torrent_file->end_files()); i != end; ++i)
{
fl.push_back(i->path);
}
}
// write local peers
std::back_insert_iterator<entry::string_type> peers(ret["peers"].string());
std::back_insert_iterator<entry::string_type> banned_peers(ret["banned_peers"].string());
#if TORRENT_USE_IPV6
std::back_insert_iterator<entry::string_type> peers6(ret["peers6"].string());
std::back_insert_iterator<entry::string_type> banned_peers6(ret["banned_peers6"].string());
#endif
// failcount is a 5 bit value
int max_failcount = (std::min)(settings().max_failcount, 31);
for (policy::const_iterator i = m_policy.begin_peer()
, end(m_policy.end_peer()); i != end; ++i)
{
error_code ec;
policy::peer const* p = *i;
address addr = p->address();
if (p->banned)
{
#if TORRENT_USE_IPV6
if (addr.is_v6())
write_endpoint(tcp::endpoint(addr, p->port), banned_peers6);
else
#endif
write_endpoint(tcp::endpoint(addr, p->port), banned_peers);
continue;
}
// we cannot save remote connection
// since we don't know their listen port
// unless they gave us their listen port
// through the extension handshake
// so, if the peer is not connectable (i.e. we
// don't know its listen port) or if it has
// been banned, don't save it.
if (!p->connectable) continue;
// don't save peers that don't work
if (int(p->failcount) >= max_failcount) continue;
#if TORRENT_USE_IPV6
if (addr.is_v6())
write_endpoint(tcp::endpoint(addr, p->port), peers6);
else
#endif
write_endpoint(tcp::endpoint(addr, p->port), peers);
}
ret["upload_rate_limit"] = upload_limit();
ret["download_rate_limit"] = download_limit();
ret["max_connections"] = max_connections();
ret["max_uploads"] = max_uploads();
ret["paused"] = m_paused;
ret["auto_managed"] = m_auto_managed;
// write piece priorities
entry::string_type& piece_priority = ret["piece_priority"].string();
piece_priority.resize(m_torrent_file->num_pieces());
if (is_seed())
{
std::memset(&piece_priority[0], 1, pieces.size());
}
else
{
for (int i = 0, end(piece_priority.size()); i < end; ++i)
piece_priority[i] = m_picker->piece_priority(i);
}
// write file priorities
entry::list_type& file_priority = ret["file_priority"].list();
file_priority.clear();
for (int i = 0, end(m_file_priority.size()); i < end; ++i)
file_priority.push_back(m_file_priority[i]);
}
void torrent::get_full_peer_list(std::vector<peer_list_entry>& v) const
{
v.clear();
v.reserve(m_policy.num_peers());
for (policy::const_iterator i = m_policy.begin_peer();
i != m_policy.end_peer(); ++i)
{
peer_list_entry e;
e.ip = (*i)->ip();
e.flags = (*i)->banned ? peer_list_entry::banned : 0;
e.failcount = (*i)->failcount;
e.source = (*i)->source;
v.push_back(e);
}
}
void torrent::get_peer_info(std::vector<peer_info>& v)
{
v.clear();
for (peer_iterator i = begin();
i != end(); ++i)
{
peer_connection* peer = *i;
// incoming peers that haven't finished the handshake should
// not be included in this list
if (peer->associated_torrent().expired()) continue;
v.push_back(peer_info());
peer_info& p = v.back();
peer->get_peer_info(p);
#ifndef TORRENT_DISABLE_RESOLVE_COUNTRIES
if (resolving_countries())
resolve_peer_country(intrusive_ptr<peer_connection>(peer));
#endif
}
}
void torrent::get_download_queue(std::vector<partial_piece_info>& queue)
{
queue.clear();
std::vector<block_info>& blk = m_ses.m_block_info_storage;
blk.clear();
if (!valid_metadata() || is_seed()) return;
piece_picker const& p = picker();
std::vector<piece_picker::downloading_piece> const& q
= p.get_download_queue();
const int blocks_per_piece = m_picker->blocks_in_piece(0);
blk.resize(q.size() * blocks_per_piece);
int counter = 0;
for (std::vector<piece_picker::downloading_piece>::const_iterator i
= q.begin(); i != q.end(); ++i, ++counter)
{
partial_piece_info pi;
pi.piece_state = (partial_piece_info::state_t)i->state;
pi.blocks_in_piece = p.blocks_in_piece(i->index);
pi.finished = (int)i->finished;
pi.writing = (int)i->writing;
pi.requested = (int)i->requested;
pi.blocks = &blk[counter * blocks_per_piece];
int piece_size = int(torrent_file().piece_size(i->index));
for (int j = 0; j < pi.blocks_in_piece; ++j)
{
block_info& bi = pi.blocks[j];
bi.state = i->info[j].state;
bi.block_size = j < pi.blocks_in_piece - 1 ? block_size()
: piece_size - (j * block_size());
bool complete = bi.state == block_info::writing
|| bi.state == block_info::finished;
if (i->info[j].peer == 0)
{
bi.set_peer(tcp::endpoint());
bi.bytes_progress = complete ? bi.block_size : 0;
}
else
{
policy::peer* p = static_cast<policy::peer*>(i->info[j].peer);
if (p->connection)
{
bi.set_peer(p->connection->remote());
if (bi.state == block_info::requested)
{
boost::optional<piece_block_progress> pbp
= p->connection->downloading_piece_progress();
if (pbp && pbp->piece_index == i->index && pbp->block_index == j)
{
bi.bytes_progress = pbp->bytes_downloaded;
TORRENT_ASSERT(bi.bytes_progress <= bi.block_size);
}
else
{
bi.bytes_progress = 0;
}
}
else
{
bi.bytes_progress = complete ? bi.block_size : 0;
}
}
else
{
bi.set_peer(p->ip());
bi.bytes_progress = complete ? bi.block_size : 0;
}
}
pi.blocks[j].num_peers = i->info[j].num_peers;
}
pi.piece_index = i->index;
queue.push_back(pi);
}
}
bool torrent::connect_to_peer(policy::peer* peerinfo)
{
INVARIANT_CHECK;
TORRENT_ASSERT(peerinfo);
TORRENT_ASSERT(peerinfo->connection == 0);
peerinfo->last_connected = m_ses.session_time();
#ifdef TORRENT_DEBUG
// this asserts that we don't have duplicates in the policy's peer list
peer_iterator i_ = std::find_if(m_connections.begin(), m_connections.end()
, bind(&peer_connection::remote, _1) == peerinfo->ip());
#if TORRENT_USE_I2P
TORRENT_ASSERT(i_ == m_connections.end()
|| (*i_)->type() != peer_connection::bittorrent_connection
|| peerinfo->is_i2p_addr
);
#else
TORRENT_ASSERT(i_ == m_connections.end()
|| (*i_)->type() != peer_connection::bittorrent_connection
);
#endif
#endif
TORRENT_ASSERT(want_more_peers());
TORRENT_ASSERT(m_ses.num_connections() < m_ses.max_connections());
tcp::endpoint a(peerinfo->ip());
TORRENT_ASSERT((m_ses.m_ip_filter.access(peerinfo->address()) & ip_filter::blocked) == 0);
boost::shared_ptr<socket_type> s(new socket_type(m_ses.m_io_service));
#if TORRENT_USE_I2P
bool i2p = peerinfo->is_i2p_addr;
if (i2p)
{
bool ret = instantiate_connection(m_ses.m_io_service, m_ses.i2p_proxy(), *s);
(void)ret;
TORRENT_ASSERT(ret);
s->get<i2p_stream>()->set_destination(static_cast<policy::i2p_peer*>(peerinfo)->destination);
s->get<i2p_stream>()->set_command(i2p_stream::cmd_connect);
s->get<i2p_stream>()->set_session_id(m_ses.m_i2p_conn.session_id());
}
else
#endif
{
bool ret = instantiate_connection(m_ses.m_io_service, m_ses.peer_proxy(), *s);
(void)ret;
TORRENT_ASSERT(ret);
}
m_ses.setup_socket_buffers(*s);
boost::intrusive_ptr<peer_connection> c(new bt_peer_connection(
m_ses, shared_from_this(), s, a, peerinfo));
#ifdef TORRENT_DEBUG
c->m_in_constructor = false;
#endif
if (settings().default_peer_upload_rate)
c->set_upload_limit(settings().default_peer_upload_rate);
if (settings().default_peer_download_rate)
c->set_download_limit(settings().default_peer_download_rate);
c->add_stat(peerinfo->prev_amount_download, peerinfo->prev_amount_upload);
peerinfo->prev_amount_download = 0;
peerinfo->prev_amount_upload = 0;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
#ifndef BOOST_NO_EXCEPTIONS
try {
#endif
boost::shared_ptr<peer_plugin> pp((*i)->new_connection(c.get()));
if (pp) c->add_extension(pp);
#ifndef BOOST_NO_EXCEPTIONS
} catch (std::exception&) {}
#endif
}
#endif
// add the newly connected peer to this torrent's peer list
m_connections.insert(boost::get_pointer(c));
m_ses.m_connections.insert(c);
m_policy.set_connection(peerinfo, c.get());
c->start();
int timeout = settings().peer_connect_timeout;
if (peerinfo) timeout += 3 * peerinfo->failcount;
#ifndef BOOST_NO_EXCEPTIONS
try
{
#endif
m_ses.m_half_open.enqueue(
bind(&peer_connection::on_connect, c, _1)
, bind(&peer_connection::on_timeout, c)
, seconds(timeout));
#ifndef BOOST_NO_EXCEPTIONS
}
catch (std::exception& e)
{
std::set<peer_connection*>::iterator i
= m_connections.find(boost::get_pointer(c));
if (i != m_connections.end()) m_connections.erase(i);
c->disconnect(errors::no_error, 1);
return false;
}
#endif
return peerinfo->connection;
}
bool torrent::set_metadata(char const* metadata_buf, int metadata_size)
{
INVARIANT_CHECK;
if (m_torrent_file->is_valid()) return false;
hasher h;
h.update(metadata_buf, metadata_size);
sha1_hash info_hash = h.final();
if (info_hash != m_torrent_file->info_hash())
{
if (alerts().should_post<metadata_failed_alert>())
{
alerts().post_alert(metadata_failed_alert(get_handle()));
}
return false;
}
lazy_entry metadata;
int ret = lazy_bdecode(metadata_buf, metadata_buf + metadata_size, metadata);
error_code ec;
if (ret != 0 || !m_torrent_file->parse_info_section(metadata, ec))
{
// this means the metadata is correct, since we
// verified it against the info-hash, but we
// failed to parse it. Pause the torrent
if (alerts().should_post<metadata_failed_alert>())
{
alerts().post_alert(metadata_failed_alert(get_handle()));
}
set_error(errors::invalid_swarm_metadata, "");
pause();
return false;
}
if (m_ses.m_alerts.should_post<metadata_received_alert>())
{
m_ses.m_alerts.post_alert(metadata_received_alert(
get_handle()));
}
// this makes the resume data "paused" and
// "auto_managed" fields be ignored. If the paused
// field is not ignored, the invariant check will fail
// since we will be paused but without having disconnected
// any of the peers.
m_override_resume_data = true;
init();
return true;
}
bool torrent::attach_peer(peer_connection* p)
{
// INVARIANT_CHECK;
TORRENT_ASSERT(p != 0);
TORRENT_ASSERT(!p->is_local());
m_has_incoming = true;
if ((m_state == torrent_status::queued_for_checking
|| m_state == torrent_status::checking_files
|| m_state == torrent_status::checking_resume_data)
&& valid_metadata())
{
p->disconnect(errors::torrent_not_ready);
return false;
}
if (m_ses.m_connections.find(p) == m_ses.m_connections.end())
{
p->disconnect(errors::peer_not_constructed);
return false;
}
if (m_ses.is_aborted())
{
p->disconnect(errors::session_closing);
return false;
}
if (int(m_connections.size()) >= m_max_connections)
{
p->disconnect(errors::too_many_connections);
return false;
}
#ifndef BOOST_NO_EXCEPTIONS
try
{
#endif
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
boost::shared_ptr<peer_plugin> pp((*i)->new_connection(p));
if (pp) p->add_extension(pp);
}
#endif
if (!m_policy.new_connection(*p, m_ses.session_time()))
return false;
#ifndef BOOST_NO_EXCEPTIONS
}
catch (std::exception& e)
{
#if defined TORRENT_LOGGING
(*m_ses.m_logger) << time_now_string() << " CLOSING CONNECTION "
<< p->remote() << " policy::new_connection threw: " << e.what() << "\n";
#endif
p->disconnect(errors::no_error);
return false;
}
#endif
TORRENT_ASSERT(m_connections.find(p) == m_connections.end());
peer_iterator ci = m_connections.insert(p).first;
#ifdef TORRENT_DEBUG
error_code ec;
TORRENT_ASSERT(p->remote() == p->get_socket()->remote_endpoint(ec) || ec);
#endif
#if defined TORRENT_DEBUG && !defined TORRENT_DISABLE_INVARIANT_CHECKS
m_policy.check_invariant();
#endif
return true;
}
bool torrent::want_more_peers() const
{
return int(m_connections.size()) < m_max_connections
&& !is_paused()
&& ((m_state != torrent_status::checking_files
&& m_state != torrent_status::checking_resume_data
&& m_state != torrent_status::queued_for_checking)
|| !valid_metadata())
&& m_policy.num_connect_candidates() > 0
&& !m_abort;
}
void torrent::disconnect_all(error_code const& ec)
{
// doesn't work with the m_paused -> m_num_peers == 0 condition
// INVARIANT_CHECK;
while (!m_connections.empty())
{
peer_connection* p = *m_connections.begin();
TORRENT_ASSERT(p->associated_torrent().lock().get() == this);
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
(*p->m_logger) << "*** CLOSING CONNECTION: " << ec.message() << "\n";
#endif
#ifdef TORRENT_DEBUG
std::size_t size = m_connections.size();
#endif
if (p->is_disconnecting())
m_connections.erase(m_connections.begin());
else
p->disconnect(ec);
TORRENT_ASSERT(m_connections.size() <= size);
}
}
namespace
{
// this returns true if lhs is a better disconnect candidate than rhs
bool compare_disconnect_peer(peer_connection const* lhs, peer_connection const* rhs)
{
// prefer to disconnect peers that are already disconnecting
if (lhs->is_disconnecting() != rhs->is_disconnecting())
return lhs->is_disconnecting();
// prefer to disconnect peers we're not interested in
if (lhs->is_interesting() != rhs->is_interesting())
return rhs->is_interesting();
// prefer to disconnect peers that are not seeds
if (lhs->is_seed() != rhs->is_seed())
return rhs->is_seed();
// prefer to disconnect peers that are on parole
if (lhs->on_parole() != rhs->on_parole())
return lhs->on_parole();
// prefer to disconnect peers that send data at a lower rate
size_type lhs_transferred = lhs->statistics().total_payload_download();
size_type rhs_transferred = rhs->statistics().total_payload_download();
ptime now = time_now();
size_type lhs_time_connected = total_seconds(now - lhs->connected_time());
size_type rhs_time_connected = total_seconds(now - rhs->connected_time());
lhs_transferred /= lhs_time_connected + 1;
rhs_transferred /= (rhs_time_connected + 1);
if (lhs_transferred != rhs_transferred)
return lhs_transferred < rhs_transferred;
// prefer to disconnect peers that chokes us
if (lhs->is_choked() != rhs->is_choked())
return lhs->is_choked();
return lhs->last_received() < rhs->last_received();
}
}
int torrent::disconnect_peers(int num)
{
INVARIANT_CHECK;
#ifdef TORRENT_DEBUG
for (std::set<peer_connection*>::iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
{
// make sure this peer is not a dangling pointer
TORRENT_ASSERT(m_ses.has_peer(*i));
}
#endif
int ret = 0;
while (ret < num && !m_connections.empty())
{
std::set<peer_connection*>::iterator i = std::min_element(
m_connections.begin(), m_connections.end(), compare_disconnect_peer);
peer_connection* p = *i;
++ret;
p->disconnect(errors::optimistic_disconnect);
}
return ret;
}
int torrent::bandwidth_throttle(int channel) const
{
return m_bandwidth_channel[channel].throttle();
}
// called when torrent is finished (all interesting
// pieces have been downloaded)
void torrent::finished()
{
INVARIANT_CHECK;
TORRENT_ASSERT(is_finished());
TORRENT_ASSERT(m_state != torrent_status::finished && m_state != torrent_status::seeding);
if (alerts().should_post<torrent_finished_alert>())
{
alerts().post_alert(torrent_finished_alert(
get_handle()));
}
set_state(torrent_status::finished);
set_queue_position(-1);
// we have to call completed() before we start
// disconnecting peers, since there's an assert
// to make sure we're cleared the piece picker
if (is_seed()) completed();
send_upload_only();
// disconnect all seeds
// TODO: should disconnect all peers that have the pieces we have
// not just seeds
std::vector<peer_connection*> seeds;
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
peer_connection* p = *i;
TORRENT_ASSERT(p->associated_torrent().lock().get() == this);
if (p->upload_only())
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
(*p->m_logger) << "*** SEED, CLOSING CONNECTION\n";
#endif
seeds.push_back(p);
}
}
std::for_each(seeds.begin(), seeds.end()
, bind(&peer_connection::disconnect, _1, errors::torrent_finished, 0));
if (m_abort) return;
m_policy.recalculate_connect_candidates();
TORRENT_ASSERT(m_storage);
// we need to keep the object alive during this operation
m_storage->async_release_files(
bind(&torrent::on_files_released, shared_from_this(), _1, _2));
}
// this is called when we were finished, but some files were
// marked for downloading, and we are no longer finished
void torrent::resume_download()
{
INVARIANT_CHECK;
TORRENT_ASSERT(!is_finished());
set_state(torrent_status::downloading);
set_queue_position((std::numeric_limits<int>::max)());
m_policy.recalculate_connect_candidates();
send_upload_only();
}
// called when torrent is complete (all pieces downloaded)
void torrent::completed()
{
m_picker.reset();
set_state(torrent_status::seeding);
if (!m_announcing) return;
ptime now = time_now();
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
{
if (i->complete_sent) continue;
i->next_announce = now;
i->min_announce = now;
}
announce_with_tracker();
}
// this will move the tracker with the given index
// to a prioritized position in the list (move it towards
// the begining) and return the new index to the tracker.
int torrent::prioritize_tracker(int index)
{
INVARIANT_CHECK;
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < int(m_trackers.size()));
if (index >= (int)m_trackers.size()) return -1;
while (index > 0 && m_trackers[index].tier == m_trackers[index-1].tier)
{
using std::swap;
swap(m_trackers[index], m_trackers[index-1]);
if (m_last_working_tracker == index) --m_last_working_tracker;
else if (m_last_working_tracker == index - 1) ++m_last_working_tracker;
--index;
}
return index;
}
int torrent::deprioritize_tracker(int index)
{
INVARIANT_CHECK;
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < int(m_trackers.size()));
if (index >= (int)m_trackers.size()) return -1;
while (index < int(m_trackers.size()) - 1 && m_trackers[index].tier == m_trackers[index + 1].tier)
{
using std::swap;
swap(m_trackers[index], m_trackers[index + 1]);
if (m_last_working_tracker == index) ++m_last_working_tracker;
else if (m_last_working_tracker == index + 1) --m_last_working_tracker;
++index;
}
return index;
}
void torrent::files_checked_lock()
{
mutex::scoped_lock l(m_ses.m_mutex);
files_checked(l);
}
void torrent::files_checked(mutex::scoped_lock const& l)
{
TORRENT_ASSERT(m_torrent_file->is_valid());
if (m_abort) return;
// we might be finished already, in which case we should
// not switch to downloading mode. If all files are
// filtered, we're finished when we start.
if (m_state != torrent_status::finished)
set_state(torrent_status::downloading);
INVARIANT_CHECK;
if (m_ses.m_alerts.should_post<torrent_checked_alert>())
{
m_ses.m_alerts.post_alert(torrent_checked_alert(
get_handle()));
}
if (!is_seed())
{
// turn off super seeding if we're not a seed
if (m_super_seeding) m_super_seeding = false;
// if we just finished checking and we're not a seed, we are
// likely to be unpaused
if (m_ses.m_auto_manage_time_scaler > 1)
m_ses.m_auto_manage_time_scaler = 1;
if (is_finished() && m_state != torrent_status::finished)
finished();
}
else
{
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
i->complete_sent = true;
if (m_state != torrent_status::finished)
finished();
}
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
#ifndef BOOST_NO_EXCEPTIONS
try {
#endif
(*i)->on_files_checked();
#ifndef BOOST_NO_EXCEPTIONS
} catch (std::exception&) {}
#endif
}
#endif
if (!m_connections_initialized)
{
m_connections_initialized = true;
// all peer connections have to initialize themselves now that the metadata
// is available
for (torrent::peer_iterator i = m_connections.begin();
i != m_connections.end();)
{
peer_connection* pc = *i;
++i;
if (pc->is_disconnecting()) continue;
pc->on_metadata_impl();
if (pc->is_disconnecting()) continue;
pc->init();
}
}
m_files_checked = true;
start_announcing();
}
alert_manager& torrent::alerts() const
{
return m_ses.m_alerts;
}
std::string torrent::save_path() const
{
return m_save_path;
}
bool torrent::rename_file(int index, std::string const& name)
{
INVARIANT_CHECK;
TORRENT_ASSERT(index >= 0);
TORRENT_ASSERT(index < m_torrent_file->num_files());
if (!m_owning_storage.get()) return false;
m_owning_storage->async_rename_file(index, name
, bind(&torrent::on_file_renamed, shared_from_this(), _1, _2));
return true;
}
void torrent::move_storage(std::string const& save_path)
{
INVARIANT_CHECK;
if (m_owning_storage.get())
{
m_owning_storage->async_move_storage(save_path
, bind(&torrent::on_storage_moved, shared_from_this(), _1, _2));
}
else
{
m_save_path = save_path;
if (alerts().should_post<storage_moved_alert>())
{
alerts().post_alert(storage_moved_alert(get_handle(), m_save_path));
}
}
}
void torrent::on_storage_moved(int ret, disk_io_job const& j)
{
mutex::scoped_lock l(m_ses.m_mutex);
if (ret == 0)
{
if (alerts().should_post<storage_moved_alert>())
{
alerts().post_alert(storage_moved_alert(get_handle(), j.str));
}
m_save_path = j.str;
}
else
{
if (alerts().should_post<storage_moved_failed_alert>())
{
alerts().post_alert(storage_moved_failed_alert(get_handle(), j.error));
}
}
}
piece_manager& torrent::filesystem()
{
TORRENT_ASSERT(m_owning_storage.get());
TORRENT_ASSERT(m_storage);
return *m_storage;
}
torrent_handle torrent::get_handle()
{
return torrent_handle(shared_from_this());
}
session_settings const& torrent::settings() const
{
return m_ses.settings();
}
#ifdef TORRENT_DEBUG
void torrent::check_invariant() const
{
if (is_paused()) TORRENT_ASSERT(num_peers() == 0);
if (!should_check_files())
TORRENT_ASSERT(m_state != torrent_status::checking_files);
else
TORRENT_ASSERT(m_queued_for_checking);
if (!m_ses.m_queued_for_checking.empty())
{
// if there are torrents waiting to be checked
// assert that there's a torrent that is being
// processed right now
int found = 0;
int found_active = 0;
for (aux::session_impl::torrent_map::iterator i = m_ses.m_torrents.begin()
, end(m_ses.m_torrents.end()); i != end; ++i)
if (i->second->m_state == torrent_status::checking_files)
{
++found;
if (i->second->should_check_files()) ++found_active;
}
// the case of 2 is in the special case where one switches over from
// checking to complete.
TORRENT_ASSERT(found_active >= 1);
TORRENT_ASSERT(found_active <= 2);
TORRENT_ASSERT(found >= 1);
}
TORRENT_ASSERT(m_resume_entry.type() == lazy_entry::dict_t
|| m_resume_entry.type() == lazy_entry::none_t);
int num_uploads = 0;
std::map<piece_block, int> num_requests;
for (const_peer_iterator i = begin(); i != end(); ++i)
{
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
// make sure this peer is not a dangling pointer
TORRENT_ASSERT(m_ses.has_peer(*i));
#endif
peer_connection const& p = *(*i);
for (std::vector<pending_block>::const_iterator i = p.request_queue().begin()
, end(p.request_queue().end()); i != end; ++i)
++num_requests[i->block];
for (std::vector<pending_block>::const_iterator i = p.download_queue().begin()
, end(p.download_queue().end()); i != end; ++i)
if (!i->not_wanted && !i->timed_out) ++num_requests[i->block];
if (!p.is_choked() && !p.ignore_unchoke_slots()) ++num_uploads;
torrent* associated_torrent = p.associated_torrent().lock().get();
if (associated_torrent != this)
TORRENT_ASSERT(false);
}
TORRENT_ASSERT(num_uploads == m_num_uploads);
if (has_picker())
{
for (std::map<piece_block, int>::iterator i = num_requests.begin()
, end(num_requests.end()); i != end; ++i)
{
piece_block b = i->first;
int count = i->second;
int picker_count = m_picker->num_peers(b);
if (!m_picker->is_downloaded(b))
TORRENT_ASSERT(picker_count == count);
}
TORRENT_ASSERT(num_have() >= m_picker->num_have_filtered());
}
if (valid_metadata())
{
TORRENT_ASSERT(m_abort || m_error || !m_picker || m_picker->num_pieces() == m_torrent_file->num_pieces());
}
else
{
TORRENT_ASSERT(m_abort || m_error || !m_picker || m_picker->num_pieces() == 0);
}
#ifdef TORRENT_EXPENSIVE_INVARIANT_CHECKS
// make sure we haven't modified the peer object
// in a way that breaks the sort order
if (m_policy.begin_peer() != m_policy.end_peer())
{
policy::const_iterator i = m_policy.begin_peer();
policy::const_iterator prev = i++;
policy::const_iterator end(m_policy.end_peer());
policy::peer_address_compare cmp;
for (; i != end; ++i, ++prev)
{
TORRENT_ASSERT(!cmp(*i, *prev));
}
}
#endif
size_type total_done = quantized_bytes_done();
if (m_torrent_file->is_valid())
{
if (is_seed())
TORRENT_ASSERT(total_done == m_torrent_file->total_size());
else
TORRENT_ASSERT(total_done != m_torrent_file->total_size() || !m_files_checked);
TORRENT_ASSERT(block_size() <= m_torrent_file->piece_length());
}
else
{
TORRENT_ASSERT(total_done == 0);
}
if (m_picker && !m_abort)
{
// make sure that pieces that have completed the download
// of all their blocks are in the disk io thread's queue
// to be checked.
const std::vector<piece_picker::downloading_piece>& dl_queue
= m_picker->get_download_queue();
for (std::vector<piece_picker::downloading_piece>::const_iterator i =
dl_queue.begin(); i != dl_queue.end(); ++i)
{
const int blocks_per_piece = m_picker->blocks_in_piece(i->index);
bool complete = true;
for (int j = 0; j < blocks_per_piece; ++j)
{
if (i->info[j].state == piece_picker::block_info::state_finished)
continue;
complete = false;
break;
}
}
}
if (m_files_checked && valid_metadata())
{
TORRENT_ASSERT(block_size() > 0);
}
// if (is_seed()) TORRENT_ASSERT(m_picker.get() == 0);
for (std::vector<size_type>::const_iterator i = m_file_progress.begin()
, end(m_file_progress.end()); i != end; ++i)
{
int index = i - m_file_progress.begin();
TORRENT_ASSERT(*i <= m_torrent_file->files().at(index).size);
}
}
#endif
void torrent::set_sequential_download(bool sd)
{ m_sequential_download = sd; }
void torrent::set_queue_position(int p)
{
TORRENT_ASSERT((p == -1) == is_finished()
|| (!m_auto_managed && p == -1)
|| (m_abort && p == -1));
if (is_finished() && p != -1) return;
if (p == m_sequence_number) return;
session_impl::torrent_map& torrents = m_ses.m_torrents;
if (p >= 0 && m_sequence_number == -1)
{
int max_seq = -1;
for (session_impl::torrent_map::iterator i = torrents.begin()
, end(torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
if (t->m_sequence_number > max_seq) max_seq = t->m_sequence_number;
}
m_sequence_number = (std::min)(max_seq + 1, p);
}
else if (p < 0)
{
for (session_impl::torrent_map::iterator i = torrents.begin()
, end(torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
if (t == this) continue;
if (t->m_sequence_number >= m_sequence_number
&& t->m_sequence_number != -1)
--t->m_sequence_number;
}
m_sequence_number = p;
}
else if (p < m_sequence_number)
{
for (session_impl::torrent_map::iterator i = torrents.begin()
, end(torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
if (t == this) continue;
if (t->m_sequence_number >= p
&& t->m_sequence_number < m_sequence_number
&& t->m_sequence_number != -1)
++t->m_sequence_number;
}
m_sequence_number = p;
}
else if (p > m_sequence_number)
{
int max_seq = 0;
for (session_impl::torrent_map::iterator i = torrents.begin()
, end(torrents.end()); i != end; ++i)
{
torrent* t = i->second.get();
int pos = t->m_sequence_number;
if (pos > max_seq) max_seq = pos;
if (t == this) continue;
if (pos <= p
&& pos > m_sequence_number
&& pos != -1)
--t->m_sequence_number;
}
m_sequence_number = (std::min)(max_seq, p);
}
if (m_ses.m_auto_manage_time_scaler > 2)
m_ses.m_auto_manage_time_scaler = 2;
}
void torrent::set_max_uploads(int limit)
{
TORRENT_ASSERT(limit >= -1);
if (limit <= 0) limit = (std::numeric_limits<int>::max)();
m_max_uploads = limit;
}
void torrent::set_max_connections(int limit)
{
TORRENT_ASSERT(limit >= -1);
if (limit <= 0) limit = (std::numeric_limits<int>::max)();
m_max_connections = limit;
}
void torrent::set_peer_upload_limit(tcp::endpoint ip, int limit)
{
TORRENT_ASSERT(limit >= -1);
peer_iterator i = std::find_if(m_connections.begin(), m_connections.end()
, bind(&peer_connection::remote, _1) == ip);
if (i == m_connections.end()) return;
(*i)->set_upload_limit(limit);
}
void torrent::set_peer_download_limit(tcp::endpoint ip, int limit)
{
TORRENT_ASSERT(limit >= -1);
peer_iterator i = std::find_if(m_connections.begin(), m_connections.end()
, bind(&peer_connection::remote, _1) == ip);
if (i == m_connections.end()) return;
(*i)->set_download_limit(limit);
}
void torrent::set_upload_limit(int limit)
{
TORRENT_ASSERT(limit >= -1);
if (limit <= 0) limit = 0;
m_bandwidth_channel[peer_connection::upload_channel].throttle(limit);
}
int torrent::upload_limit() const
{
int limit = m_bandwidth_channel[peer_connection::upload_channel].throttle();
if (limit == (std::numeric_limits<int>::max)()) limit = -1;
return limit;
}
void torrent::set_download_limit(int limit)
{
TORRENT_ASSERT(limit >= -1);
if (limit <= 0) limit = 0;
m_bandwidth_channel[peer_connection::download_channel].throttle(limit);
}
int torrent::download_limit() const
{
int limit = m_bandwidth_channel[peer_connection::download_channel].throttle();
if (limit == (std::numeric_limits<int>::max)()) limit = -1;
return limit;
}
void torrent::delete_files()
{
#if defined TORRENT_VERBOSE_LOGGING
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
(*(*i)->m_logger) << "*** DELETING FILES IN TORRENT\n";
}
#endif
disconnect_all(errors::torrent_removed);
stop_announcing();
if (m_owning_storage.get())
{
TORRENT_ASSERT(m_storage);
m_storage->async_delete_files(
bind(&torrent::on_files_deleted, shared_from_this(), _1, _2));
}
}
void torrent::clear_error()
{
if (!m_error) return;
bool checking_files = should_check_files();
if (m_ses.m_auto_manage_time_scaler > 2)
m_ses.m_auto_manage_time_scaler = 2;
m_error = error_code();
m_error_file.clear();
// if the error happened during initialization, try again now
if (!m_storage) init();
if (!checking_files && should_check_files())
queue_torrent_check();
}
void torrent::set_error(error_code const& ec, std::string const& error_file)
{
bool checking_files = should_check_files();
m_error = ec;
m_error_file = error_file;
if (checking_files && !should_check_files())
{
// stop checking
m_storage->abort_disk_io();
dequeue_torrent_check();
set_state(torrent_status::queued_for_checking);
}
}
void torrent::auto_managed(bool a)
{
INVARIANT_CHECK;
if (m_auto_managed == a) return;
bool checking_files = should_check_files();
m_auto_managed = a;
// recalculate which torrents should be
// paused
m_ses.m_auto_manage_time_scaler = 0;
if (!checking_files && should_check_files())
{
queue_torrent_check();
}
else if (checking_files && !should_check_files())
{
// stop checking
m_storage->abort_disk_io();
dequeue_torrent_check();
set_state(torrent_status::queued_for_checking);
}
}
// the higher seed rank, the more important to seed
int torrent::seed_rank(session_settings const& s) const
{
enum flags
{
seed_ratio_not_met = 0x400000,
recently_started = 0x200000,
no_seeds = 0x100000,
prio_mask = 0xfffff
};
if (!is_finished()) return 0;
int scale = 100;
if (!is_seed()) scale = 50;
int ret = 0;
ptime now = time_now();
int finished_time = m_finished_time;
int download_time = int(m_active_time) - finished_time;
// if we haven't yet met the seed limits, set the seed_ratio_not_met
// flag. That will make this seed prioritized
// downloaded may be 0 if the torrent is 0-sized
size_type downloaded = (std::max)(m_total_downloaded, m_torrent_file->total_size());
if (finished_time < s.seed_time_limit
&& (download_time > 1 && finished_time / download_time < s.seed_time_ratio_limit)
&& downloaded > 0
&& m_total_uploaded / downloaded < s.share_ratio_limit)
ret |= seed_ratio_not_met;
// if this torrent is running, and it was started less
// than 30 minutes ago, give it priority, to avoid oscillation
if (!is_paused() && now - m_started < minutes(30))
ret |= recently_started;
// if we have any scrape data, use it to calculate
// seed rank
int seeds = 0;
int downloaders = 0;
if (m_complete >= 0) seeds = m_complete;
else seeds = m_policy.num_seeds();
if (m_incomplete >= 0) downloaders = m_incomplete;
else downloaders = m_policy.num_peers() - m_policy.num_seeds();
if (seeds == 0)
{
ret |= no_seeds;
ret |= downloaders & prio_mask;
}
else
{
ret |= (downloaders * scale / seeds) & prio_mask;
}
return ret;
}
// this is an async operation triggered by the client
void torrent::save_resume_data()
{
INVARIANT_CHECK;
if (!m_owning_storage.get())
{
alerts().post_alert(save_resume_data_failed_alert(get_handle()
, errors::destructing_torrent));
return;
}
TORRENT_ASSERT(m_storage);
if (m_state == torrent_status::queued_for_checking
|| m_state == torrent_status::checking_files
|| m_state == torrent_status::checking_resume_data)
{
boost::shared_ptr<entry> rd(new entry);
write_resume_data(*rd);
alerts().post_alert(save_resume_data_alert(rd
, get_handle()));
return;
}
m_storage->async_save_resume_data(
bind(&torrent::on_save_resume_data, shared_from_this(), _1, _2));
}
bool torrent::should_check_files() const
{
return (m_state == torrent_status::checking_files
|| m_state == torrent_status::queued_for_checking)
&& (!m_paused || m_auto_managed)
&& !has_error()
&& !m_abort;
}
void torrent::flush_cache()
{
m_storage->async_release_files(
bind(&torrent::on_cache_flushed, shared_from_this(), _1, _2));
}
void torrent::on_cache_flushed(int ret, disk_io_job const& j)
{
if (alerts().should_post<cache_flushed_alert>())
alerts().post_alert(cache_flushed_alert(get_handle()));
}
bool torrent::is_paused() const
{
return m_paused || m_ses.is_paused();
}
void torrent::pause()
{
INVARIANT_CHECK;
if (m_paused) return;
bool checking_files = should_check_files();
m_paused = true;
if (!m_ses.is_paused())
do_pause();
if (checking_files && !should_check_files())
{
// stop checking
m_storage->abort_disk_io();
dequeue_torrent_check();
set_state(torrent_status::queued_for_checking);
}
}
void torrent::do_pause()
{
if (!is_paused()) return;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
#ifndef BOOST_NO_EXCEPTIONS
try {
#endif
if ((*i)->on_pause()) return;
#ifndef BOOST_NO_EXCEPTIONS
} catch (std::exception&) {}
#endif
}
#endif
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
for (peer_iterator i = m_connections.begin();
i != m_connections.end(); ++i)
{
(*(*i)->m_logger) << "*** PAUSING TORRENT\n";
}
#endif
// this will make the storage close all
// files and flush all cached data
if (m_owning_storage.get())
{
TORRENT_ASSERT(m_storage);
m_storage->async_release_files(
bind(&torrent::on_torrent_paused, shared_from_this(), _1, _2));
m_storage->async_clear_read_cache();
}
else
{
if (alerts().should_post<torrent_paused_alert>())
alerts().post_alert(torrent_paused_alert(get_handle()));
}
disconnect_all(errors::torrent_paused);
stop_announcing();
}
void torrent::resume()
{
INVARIANT_CHECK;
if (!m_paused) return;
bool checking_files = should_check_files();
m_paused = false;
do_resume();
if (!checking_files && should_check_files())
queue_torrent_check();
}
void torrent::do_resume()
{
if (is_paused()) return;
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
#ifndef BOOST_NO_EXCEPTIONS
try {
#endif
if ((*i)->on_resume()) return;
#ifndef BOOST_NO_EXCEPTIONS
} catch (std::exception&) {}
#endif
}
#endif
if (alerts().should_post<torrent_resumed_alert>())
alerts().post_alert(torrent_resumed_alert(get_handle()));
m_started = time_now();
clear_error();
start_announcing();
}
void torrent::update_tracker_timer()
{
if (!m_announcing) return;
ptime next_announce = max_time();
int tier = INT_MAX;
bool found_working = false;
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
{
if (settings().announce_to_all_tiers
&& found_working
&& i->tier <= tier
&& tier != INT_MAX)
continue;
if (i->tier > tier && !settings().announce_to_all_tiers) break;
if (i->is_working()) { tier = i->tier; found_working = false; }
if (i->fails >= i->fail_limit && i->fail_limit != 0) continue;
if (i->updating) { found_working = true; continue; }
if (i->is_working())
{
ptime next_tracker_announce = (std::max)(i->next_announce, i->min_announce);
if (!i->updating && next_tracker_announce < next_announce) next_announce = next_tracker_announce;
found_working = true;
if (!settings().announce_to_all_trackers
&& !settings().announce_to_all_tiers) break;
}
}
if (next_announce == max_time()) return;
// since we don't know if we have to re-issue the async_wait or not
// always do it
// if (m_tracker_timer.expires_at() <= next_announce) return;
error_code ec;
boost::weak_ptr<torrent> self(shared_from_this());
m_tracker_timer.expires_at(next_announce, ec);
m_tracker_timer.async_wait(bind(&torrent::on_tracker_announce_disp, self, _1));
m_waiting_tracker = true;
}
void torrent::start_announcing()
{
if (is_paused()) return;
// if we don't have metadata, we need to announce
// before checking files, to get peers to
// request the metadata from
if (!m_files_checked && valid_metadata()) return;
if (m_announcing) return;
m_announcing = true;
if (!m_trackers.empty())
{
// tell the tracker that we're back
std::for_each(m_trackers.begin(), m_trackers.end()
, bind(&announce_entry::reset, _1));
}
// reset the stats, since from the tracker's
// point of view, this is a new session
m_total_failed_bytes = 0;
m_total_redundant_bytes = 0;
m_stat.clear();
announce_with_tracker();
// private torrents are never announced on LSD
// or on DHT, we don't need this timer.
if (!m_torrent_file->is_valid()
|| (!m_torrent_file->priv()
&& (!m_torrent_file->is_i2p()
|| settings().allow_i2p_mixed)))
{
if (m_ses.m_lsd) lsd_announce();
#ifndef TORRENT_DISABLE_DHT
if (m_ses.m_dht) dht_announce();
#endif
}
}
void torrent::stop_announcing()
{
if (!m_announcing) return;
error_code ec;
m_tracker_timer.cancel(ec);
m_announcing = false;
ptime now = time_now();
for (std::vector<announce_entry>::iterator i = m_trackers.begin()
, end(m_trackers.end()); i != end; ++i)
{
i->next_announce = now;
i->min_announce = now;
}
announce_with_tracker(tracker_request::stopped);
}
void torrent::second_tick(stat& accumulator, int tick_interval_ms)
{
INVARIANT_CHECK;
ptime now = time_now();
#ifndef TORRENT_DISABLE_EXTENSIONS
for (extension_list_t::iterator i = m_extensions.begin()
, end(m_extensions.end()); i != end; ++i)
{
#ifndef BOOST_NO_EXCEPTIONS
try {
#endif
(*i)->tick();
#ifndef BOOST_NO_EXCEPTIONS
} catch (std::exception&) {}
#endif
}
#endif
m_time_scaler--;
if (m_time_scaler <= 0)
{
m_time_scaler = 10;
if (settings().max_sparse_regions > 0
&& m_picker
&& m_picker->sparse_regions() > settings().max_sparse_regions)
{
// we have too many sparse regions. Prioritize pieces
// that won't introduce new sparse regions
// prioritize pieces that will reduce the number of sparse
// regions even higher
int start = m_picker->cursor();
int end = m_picker->reverse_cursor();
for (int i = start; i < end; ++i)
update_sparse_piece_prio(i, start, end);
}
// ------------------------
// upload shift
// ------------------------
// this part will shift downloads
// from peers that are seeds and peers
// that don't want to download from us
// to peers that cannot upload anything
// to us. The shifting will make sure
// that the torrent's share ratio
// will be maintained
// if the share ratio is 0 (infinite)
// m_available_free_upload isn't used
// because it isn't necessary
if (ratio() != 0.f)
{
// accumulate all the free download we get
// and add it to the available free upload
m_available_free_upload += collect_free_download(
this->begin(), this->end());
// distribute the free upload among the peers
m_available_free_upload = distribute_free_upload(
this->begin(), this->end(), m_available_free_upload);
}
m_policy.pulse();
}
// if we're in upload only mode and we're auto-managed
// leave upload mode every 10 minutes hoping that the error
// condition has been fixed
if (m_upload_mode && m_auto_managed && m_upload_mode_time
>= settings().optimistic_disk_retry)
{
set_upload_mode(false);
}
if (is_paused())
{
// let the stats fade out to 0
accumulator += m_stat;
m_stat.second_tick(tick_interval_ms);
return;
}
if (settings().rate_limit_ip_overhead)
{
int up_limit = m_bandwidth_channel[peer_connection::upload_channel].throttle();
int down_limit = m_bandwidth_channel[peer_connection::download_channel].throttle();
if (down_limit > 0
&& m_stat.download_ip_overhead() >= down_limit
&& alerts().should_post<performance_alert>())
{
alerts().post_alert(performance_alert(get_handle()
, performance_alert::download_limit_too_low));
}
if (up_limit > 0
&& m_stat.upload_ip_overhead() >= up_limit
&& alerts().should_post<performance_alert>())
{
alerts().post_alert(performance_alert(get_handle()
, performance_alert::upload_limit_too_low));
}
}
int seconds_since_last_tick = 1;
if (m_ses.m_tick_residual >= 1000) ++seconds_since_last_tick;
if (is_seed()) m_seeding_time += seconds_since_last_tick;
if (is_finished()) m_finished_time += seconds_since_last_tick;
if (m_upload_mode) m_upload_mode_time += seconds_since_last_tick;
m_last_scrape += seconds_since_last_tick;
m_active_time += seconds_since_last_tick;
// ---- TIME CRITICAL PIECES ----
if (!m_time_critical_pieces.empty())
{
request_time_critical_pieces();
}
// ---- WEB SEEDS ----
// if we have everything we want we don't need to connect to any web-seed
if (!is_finished() && !m_web_seeds.empty() && m_files_checked)
{
// keep trying web-seeds if there are any
// first find out which web seeds we are connected to
for (std::list<web_seed_entry>::iterator i = m_web_seeds.begin();
i != m_web_seeds.end();)
{
std::list<web_seed_entry>::iterator w = i++;
if (w->connection) continue;
if (w->retry > time_now()) continue;
if (w->resolving) continue;
connect_to_url_seed(w);
}
}
for (peer_iterator i = m_connections.begin();
i != m_connections.end();)
{
peer_connection* p = *i;
++i;
m_stat += p->statistics();
// updates the peer connection's ul/dl bandwidth
// resource requests
#ifndef BOOST_NO_EXCEPTIONS
try
{
#endif
p->second_tick(tick_interval_ms);
#ifndef BOOST_NO_EXCEPTIONS
}
catch (std::exception& e)
{
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_ERROR_LOGGING
(*p->m_logger) << "**ERROR**: " << e.what() << "\n";
#endif
p->disconnect(errors::no_error, 1);
}
#endif
}
if (m_ses.m_alerts.should_post<stats_alert>())
m_ses.m_alerts.post_alert(stats_alert(get_handle(), tick_interval_ms, m_stat));
accumulator += m_stat;
m_total_uploaded += m_stat.last_payload_uploaded();
m_total_downloaded += m_stat.last_payload_downloaded();
m_stat.second_tick(tick_interval_ms);
}
void torrent::refresh_explicit_cache(int cache_size)
{
if (!ready_for_connections()) return;
// rotate the cached pieces
// add blocks_per_piece / 2 in order to round to closest whole piece
int blocks_per_piece = m_torrent_file->piece_length() / block_size();
int num_cache_pieces = (cache_size + blocks_per_piece / 2) / blocks_per_piece;
if (num_cache_pieces > m_torrent_file->num_pieces())
num_cache_pieces = m_torrent_file->num_pieces();
std::vector<int> avail_vec;
if (has_picker())
{
m_picker->get_availability(avail_vec);
}
else
{
// we don't keep track of availability, do it the expensive way
// do a linear search from the first piece
for (int i = 0; i < m_torrent_file->num_pieces(); ++i)
{
int availability = 0;
if (!have_piece(i))
{
avail_vec.push_back(INT_MAX);
continue;
}
for (const_peer_iterator j = this->begin(); j != this->end(); ++j)
if ((*j)->has_piece(i)) ++availability;
avail_vec.push_back(availability);
}
}
// now pick the num_cache_pieces rarest pieces from avail_vec
std::vector<std::pair<int, int> > pieces(m_torrent_file->num_pieces());
for (int i = 0; i < m_torrent_file->num_pieces(); ++i)
{
pieces[i].second = i;
if (!have_piece(i)) pieces[i].first = INT_MAX;
else pieces[i].first = avail_vec[i];
}
// decrease the availability of the pieces that are
// already in the read cache, to move them closer to
// the beginning of the pieces list, and more likely
// to be included in this round of cache pieces
std::vector<cached_piece_info> ret;
m_ses.m_disk_thread.get_cache_info(info_hash(), ret);
// remove write cache entries
ret.erase(std::remove_if(ret.begin(), ret.end()
, boost::bind(&cached_piece_info::kind, _1) == cached_piece_info::write_cache)
, ret.end());
for (std::vector<cached_piece_info>::iterator i = ret.begin()
, end(ret.end()); i != end; ++i)
{
--pieces[i->piece].first;
}
std::random_shuffle(pieces.begin(), pieces.end());
std::stable_sort(pieces.begin(), pieces.end()
, boost::bind(&std::pair<int, int>::first, _1) <
boost::bind(&std::pair<int, int>::first, _2));
avail_vec.clear();
for (int i = 0; i < num_cache_pieces; ++i)
{
if (pieces[i].first == INT_MAX) break;
avail_vec.push_back(pieces[i].second);
}
if (!avail_vec.empty())
{
// the number of pieces to cache for this torrent is proportional
// the number of peers it has, divided by the total number of peers.
// Each peer gets an equal share of the cache
avail_vec.resize((std::min)(num_cache_pieces, int(avail_vec.size())));
for (std::vector<int>::iterator i = avail_vec.begin()
, end(avail_vec.end()); i != end; ++i)
filesystem().async_cache(*i, bind(&torrent::on_disk_cache_complete
, shared_from_this(), _1, _2));
}
}
void torrent::get_suggested_pieces(std::vector<int>& s) const
{
if (settings().suggest_mode == session_settings::no_piece_suggestions)
{
s.clear();
return;
}
std::vector<cached_piece_info> ret;
m_ses.m_disk_thread.get_cache_info(info_hash(), ret);
ptime now = time_now();
// remove write cache entries
ret.erase(std::remove_if(ret.begin(), ret.end()
, boost::bind(&cached_piece_info::kind, _1) == cached_piece_info::write_cache)
, ret.end());
// sort by how new the cached entry is, new pieces first
std::sort(ret.begin(), ret.end()
, boost::bind(&cached_piece_info::last_use, _1)
< boost::bind(&cached_piece_info::last_use, _2));
// cut off the oldest pieces that we don't want to suggest
// if we have an explicit cache, it's much more likely to
// stick around, so we should suggest all pieces
int num_pieces_to_suggest = int(ret.size());
if (!settings().explicit_read_cache)
num_pieces_to_suggest = (std::max)(1, int(ret.size() / 2));
ret.resize(num_pieces_to_suggest);
std::transform(ret.begin(), ret.end(), std::back_inserter(s)
, boost::bind(&cached_piece_info::piece, _1));
}
void torrent::add_stats(stat const& s)
{
// these stats are propagated to the session
// stats the next time second_tick is called
m_stat += s;
}
void torrent::request_time_critical_pieces()
{
// build a list of peers and sort it by download_queue_time
std::vector<peer_connection*> peers;
peers.reserve(m_connections.size());
std::remove_copy_if(m_connections.begin(), m_connections.end()
, std::back_inserter(peers), !boost::bind(&peer_connection::can_request_time_critical, _1));
std::sort(peers.begin(), peers.end()
, boost::bind(&peer_connection::download_queue_time, _1, 16*1024)
< boost::bind(&peer_connection::download_queue_time, _2, 16*1024));
std::set<peer_connection*> peers_with_requests;
std::vector<piece_block> interesting_blocks;
std::vector<piece_block> backup1;
std::vector<piece_block> backup2;
std::vector<int> ignore;
ptime now = time_now();
for (std::list<time_critical_piece>::iterator i = m_time_critical_pieces.begin()
, end(m_time_critical_pieces.end()); i != end; ++i)
{
if (i != m_time_critical_pieces.begin() && i->deadline > now
+ milliseconds(m_average_piece_time + m_piece_time_deviation * 4))
{
// don't request pieces whose deadline is too far in the future
break;
}
// loop until every block has been requested from
do
{
// pick the peer with the lowest download_queue_time that has i->piece
std::vector<peer_connection*>::iterator p = std::find_if(peers.begin(), peers.end()
, boost::bind(&peer_connection::has_piece, _1, i->piece));
if (p == peers.end()) break;
peer_connection& c = **p;
interesting_blocks.clear();
backup1.clear();
backup2.clear();
m_picker->add_blocks(i->piece, c.get_bitfield(), interesting_blocks
, backup1, backup2, 1, 0, c.peer_info_struct()
, ignore, piece_picker::fast, 0);
std::vector<pending_block> const& rq = c.request_queue();
bool added_request = false;
if (!interesting_blocks.empty() && std::find_if(rq.begin(), rq.end()
, has_block(interesting_blocks.front())) != rq.end())
{
c.make_time_critical(interesting_blocks.front());
added_request = true;
}
else if (!interesting_blocks.empty())
{
c.add_request(interesting_blocks.front(), peer_connection::req_time_critical);
added_request = true;
}
// TODO: if there's been long enough since we requested something
// from this piece, request one of the backup blocks (the one with
// the least number of requests to it) and update the last request
// timestamp
if (added_request)
{
peers_with_requests.insert(peers_with_requests.begin(), &c);
if (i->first_requested == min_time()) i->first_requested = now;
if (!c.can_request_time_critical())
{
peers.erase(p);
}
else
{
// resort p, since it will have a higher download_queue_time now
while (p != peers.end()-1 && (*p)->download_queue_time() > (*(p+1))->download_queue_time())
{
std::iter_swap(p, p+1);
++p;
}
}
}
} while (!interesting_blocks.empty());
}
// commit all the time critical requests
for (std::set<peer_connection*>::iterator i = peers_with_requests.begin()
, end(peers_with_requests.end()); i != end; ++i)
{
(*i)->send_block_requests();
}
}
std::set<std::string> torrent::web_seeds(web_seed_entry::type_t type) const
{
std::set<std::string> ret;
for (std::list<web_seed_entry>::const_iterator i = m_web_seeds.begin()
, end(m_web_seeds.end()); i != end; ++i)
{
if (i->type != type) continue;
ret.insert(i->url);
}
return ret;
}
void torrent::retry_web_seed(std::string const& url, web_seed_entry::type_t type, int retry)
{
std::list<web_seed_entry>::iterator i = std::find_if(m_web_seeds.begin(), m_web_seeds.end()
, (boost::bind(&web_seed_entry::url, _1) == url)
&& (boost::bind(&web_seed_entry::type, _1) == type));
if (retry == 0) retry = m_ses.settings().urlseed_wait_retry;
if (i != m_web_seeds.end()) i->retry = time_now() + seconds(retry);
}
bool torrent::try_connect_peer()
{
TORRENT_ASSERT(want_more_peers());
if (m_deficit_counter < 100) return false;
m_deficit_counter -= 100;
bool ret = m_policy.connect_one_peer(m_ses.session_time());
return ret;
}
void torrent::give_connect_points(int points)
{
TORRENT_ASSERT(points <= 100);
TORRENT_ASSERT(points > 0);
TORRENT_ASSERT(want_more_peers());
m_deficit_counter += points;
}
void torrent::async_verify_piece(int piece_index, boost::function<void(int)> const& f)
{
// INVARIANT_CHECK;
TORRENT_ASSERT(m_storage);
TORRENT_ASSERT(m_storage->refcount() > 0);
TORRENT_ASSERT(piece_index >= 0);
TORRENT_ASSERT(piece_index < m_torrent_file->num_pieces());
TORRENT_ASSERT(piece_index < (int)m_picker->num_pieces());
#ifdef TORRENT_DEBUG
if (m_picker)
{
int blocks_in_piece = m_picker->blocks_in_piece(piece_index);
for (int i = 0; i < blocks_in_piece; ++i)
{
TORRENT_ASSERT(m_picker->num_peers(piece_block(piece_index, i)) == 0);
}
}
#endif
m_storage->async_hash(piece_index, bind(&torrent::on_piece_verified
, shared_from_this(), _1, _2, f));
#if defined TORRENT_DEBUG && !defined TORRENT_DISABLE_INVARIANT_CHECKS
check_invariant();
#endif
}
void torrent::on_piece_verified(int ret, disk_io_job const& j
, boost::function<void(int)> f)
{
mutex::scoped_lock l(m_ses.m_mutex);
// return value:
// 0: success, piece passed hash check
// -1: disk failure
// -2: hash check failed
if (ret == -1) handle_disk_error(j);
f(ret);
}
tcp::endpoint torrent::current_tracker() const
{
return m_tracker_address;
}
announce_entry* torrent::find_tracker(tracker_request const& r)
{
std::vector<announce_entry>::iterator i = std::find_if(
m_trackers.begin(), m_trackers.end()
, bind(&announce_entry::url, _1) == r.url);
if (i == m_trackers.end()) return 0;
return &*i;
}
#if !TORRENT_NO_FPU
void torrent::file_progress(std::vector<float>& fp) const
{
fp.clear();
fp.resize(m_torrent_file->num_files(), 1.f);
if (is_seed()) return;
std::vector<size_type> progress;
file_progress(progress);
for (int i = 0; i < m_torrent_file->num_files(); ++i)
{
file_entry const& f = m_torrent_file->file_at(i);
if (f.size == 0) fp[i] = 1.f;
else fp[i] = float(progress[i]) / f.size;
}
}
#endif
void torrent::file_progress(std::vector<size_type>& fp, int flags) const
{
TORRENT_ASSERT(valid_metadata());
fp.resize(m_torrent_file->num_files(), 0);
if (flags & torrent_handle::piece_granularity)
{
std::copy(m_file_progress.begin(), m_file_progress.end(), fp.begin());
return;
}
if (is_seed())
{
for (int i = 0; i < m_torrent_file->num_files(); ++i)
fp[i] = m_torrent_file->files().at(i).size;
return;
}
TORRENT_ASSERT(has_picker());
for (int i = 0; i < m_torrent_file->num_files(); ++i)
{
peer_request ret = m_torrent_file->files().map_file(i, 0, 0);
size_type size = m_torrent_file->files().at(i).size;
// zero sized files are considered
// 100% done all the time
if (size == 0)
{
fp[i] = 0;
continue;
}
size_type done = 0;
while (size > 0)
{
size_type bytes_step = (std::min)(size_type(m_torrent_file->piece_size(ret.piece)
- ret.start), size);
if (m_picker->have_piece(ret.piece)) done += bytes_step;
++ret.piece;
ret.start = 0;
size -= bytes_step;
}
TORRENT_ASSERT(size == 0);
fp[i] = done;
}
const std::vector<piece_picker::downloading_piece>& q
= m_picker->get_download_queue();
for (std::vector<piece_picker::downloading_piece>::const_iterator
i = q.begin(), end(q.end()); i != end; ++i)
{
size_type offset = size_type(i->index) * m_torrent_file->piece_length();
torrent_info::file_iterator file = m_torrent_file->file_at_offset(offset);
int file_index = file - m_torrent_file->begin_files();
int num_blocks = m_picker->blocks_in_piece(i->index);
piece_picker::block_info const* info = i->info;
for (int k = 0; k < num_blocks; ++k)
{
TORRENT_ASSERT(file != m_torrent_file->end_files());
TORRENT_ASSERT(offset == size_type(i->index) * m_torrent_file->piece_length()
+ k * block_size());
TORRENT_ASSERT(offset < m_torrent_file->total_size());
while (offset >= file->offset + file->size)
{
++file;
++file_index;
}
TORRENT_ASSERT(file != m_torrent_file->end_files());
size_type block = block_size();
if (info[k].state == piece_picker::block_info::state_none)
{
offset += block;
continue;
}
if (info[k].state == piece_picker::block_info::state_requested)
{
block = 0;
policy::peer* p = static_cast<policy::peer*>(info[k].peer);
if (p && p->connection)
{
boost::optional<piece_block_progress> pbp
= p->connection->downloading_piece_progress();
if (pbp && pbp->piece_index == i->index && pbp->block_index == k)
block = pbp->bytes_downloaded;
TORRENT_ASSERT(block <= block_size());
}
if (block == 0)
{
offset += block_size();
continue;
}
}
if (offset + block > file->offset + file->size)
{
int left_over = block_size() - block;
// split the block on multiple files
while (block > 0)
{
TORRENT_ASSERT(offset <= file->offset + file->size);
size_type slice = (std::min)(file->offset + file->size - offset
, block);
fp[file_index] += slice;
offset += slice;
block -= slice;
TORRENT_ASSERT(offset <= file->offset + file->size);
if (offset == file->offset + file->size)
{
++file;
++file_index;
if (file == m_torrent_file->end_files())
{
offset += block;
break;
}
}
}
offset += left_over;
TORRENT_ASSERT(offset == size_type(i->index) * m_torrent_file->piece_length()
+ (k+1) * block_size());
}
else
{
fp[file_index] += block;
offset += block_size();
}
TORRENT_ASSERT(file_index <= m_torrent_file->num_files());
}
}
}
void torrent::set_state(torrent_status::state_t s)
{
#ifdef TORRENT_DEBUG
if (s != torrent_status::checking_files
&& s != torrent_status::queued_for_checking)
{
// the only valid transition away from queued_for_checking
// is to checking_files. One exception is to finished
// in case all the files are marked with priority 0
if (m_queued_for_checking)
{
std::vector<int> pieces;
m_picker->piece_priorities(pieces);
// make sure all pieces have priority 0
TORRENT_ASSERT(std::accumulate(pieces.begin(), pieces.end(), 0) == 0);
}
}
if (s == torrent_status::seeding)
TORRENT_ASSERT(is_seed());
if (s == torrent_status::finished)
TORRENT_ASSERT(is_finished());
if (s == torrent_status::downloading && m_state == torrent_status::finished)
TORRENT_ASSERT(!is_finished());
#endif
if (m_state == s) return;
if (m_ses.m_alerts.should_post<state_changed_alert>())
m_ses.m_alerts.post_alert(state_changed_alert(get_handle(), s, (torrent_status::state_t)m_state));
m_state = s;
}
torrent_status torrent::status(boost::uint32_t flags) const
{
INVARIANT_CHECK;
ptime now = time_now();
torrent_status st;
st.has_incoming = m_has_incoming;
if (m_error) st.error = m_error.message() + ": " + m_error_file;
st.seed_mode = m_seed_mode;
st.last_scrape = m_last_scrape;
st.upload_mode = m_upload_mode;
st.up_bandwidth_queue = 0;
st.down_bandwidth_queue = 0;
st.priority = m_priority;
st.num_peers = (int)std::count_if(m_connections.begin(), m_connections.end()
, !boost::bind(&peer_connection::is_connecting, _1));
st.list_peers = m_policy.num_peers();
st.list_seeds = m_policy.num_seeds();
st.connect_candidates = m_policy.num_connect_candidates();
st.seed_rank = seed_rank(settings());
st.all_time_upload = m_total_uploaded;
st.all_time_download = m_total_downloaded;
st.active_time = m_active_time;
st.active_time = m_active_time;
st.seeding_time = m_seeding_time;
st.storage_mode = (storage_mode_t)m_storage_mode;
st.num_complete = m_complete;
st.num_incomplete = m_incomplete;
st.paused = m_paused;
bytes_done(st, flags & torrent_handle::query_accurate_download_counters);
TORRENT_ASSERT(st.total_wanted_done >= 0);
TORRENT_ASSERT(st.total_done >= st.total_wanted_done);
// payload transfer
st.total_payload_download = m_stat.total_payload_download();
st.total_payload_upload = m_stat.total_payload_upload();
// total transfer
st.total_download = m_stat.total_payload_download()
+ m_stat.total_protocol_download();
st.total_upload = m_stat.total_payload_upload()
+ m_stat.total_protocol_upload();
// failed bytes
st.total_failed_bytes = m_total_failed_bytes;
st.total_redundant_bytes = m_total_redundant_bytes;
// transfer rate
st.download_rate = m_stat.download_rate();
st.upload_rate = m_stat.upload_rate();
st.download_payload_rate = m_stat.download_payload_rate();
st.upload_payload_rate = m_stat.upload_payload_rate();
if (m_waiting_tracker && !is_paused())
st.next_announce = boost::posix_time::seconds(
total_seconds(next_announce() - now));
else
st.next_announce = boost::posix_time::seconds(0);
if (st.next_announce.is_negative())
st.next_announce = boost::posix_time::seconds(0);
st.announce_interval = boost::posix_time::seconds(0);
if (m_last_working_tracker >= 0)
{
TORRENT_ASSERT(m_last_working_tracker < int(m_trackers.size()));
st.current_tracker = m_trackers[m_last_working_tracker].url;
}
else
{
std::vector<announce_entry>::const_iterator i;
for (i = m_trackers.begin(); i != m_trackers.end(); ++i)
{
if (!i->updating) continue;
st.current_tracker = i->url;
break;
}
}
st.num_uploads = m_num_uploads;
st.uploads_limit = m_max_uploads;
st.num_connections = int(m_connections.size());
st.connections_limit = m_max_connections;
// if we don't have any metadata, stop here
st.state = (torrent_status::state_t)m_state;
if (!valid_metadata())
{
st.state = torrent_status::downloading_metadata;
st.progress_ppm = m_progress_ppm;
#if !TORRENT_NO_FPU
st.progress = m_progress_ppm / 1000000.f;
#endif
st.block_size = 0;
return st;
}
st.block_size = block_size();
if (m_state == torrent_status::checking_files)
{
st.progress_ppm = m_progress_ppm;
#if !TORRENT_NO_FPU
st.progress = m_progress_ppm / 1000000.f;
#endif
}
else if (st.total_wanted == 0)
{
st.progress_ppm = 1000000;
st.progress = 1.f;
}
else
{
st.progress_ppm = st.total_wanted_done * 1000000
/ st.total_wanted;
#if !TORRENT_NO_FPU
st.progress = st.progress_ppm / 1000000.f;
#endif
}
if (has_picker())
{
st.sparse_regions = m_picker->sparse_regions();
int num_pieces = m_picker->num_pieces();
st.pieces.resize(num_pieces, false);
for (int i = 0; i < num_pieces; ++i)
if (m_picker->have_piece(i)) st.pieces.set_bit(i);
}
st.num_pieces = num_have();
st.num_seeds = num_seeds();
if ((flags & torrent_handle::query_distributed_copies) && m_picker.get())
{
boost::tie(st.distributed_full_copies, st.distributed_fraction) =
m_picker->distributed_copies();
#if TORRENT_NO_FPU
st.distributed_copies = -1.f;
#else
st.distributed_copies = st.distributed_full_copies
+ float(st.distributed_fraction) / 1000;
#endif
}
else
{
st.distributed_full_copies = -1;
st.distributed_fraction = -1;
st.distributed_copies = -1.f;
}
return st;
}
void torrent::add_redundant_bytes(int b)
{
TORRENT_ASSERT(b > 0);
m_total_redundant_bytes += b;
m_ses.add_redundant_bytes(b);
}
void torrent::add_failed_bytes(int b)
{
TORRENT_ASSERT(b > 0);
m_total_failed_bytes += b;
m_ses.add_failed_bytes(b);
}
int torrent::num_seeds() const
{
INVARIANT_CHECK;
int ret = 0;
for (std::set<peer_connection*>::const_iterator i = m_connections.begin()
, end(m_connections.end()); i != end; ++i)
if ((*i)->is_seed()) ++ret;
return ret;
}
// TODO: with some response codes, we should just consider
// the tracker as a failure and not retry
// it anymore
void torrent::tracker_request_error(tracker_request const& r
, int response_code, error_code const& ec, const std::string& msg
, int retry_interval)
{
mutex::scoped_lock l(m_ses.m_mutex);
INVARIANT_CHECK;
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
debug_log("*** tracker error: " + ec.message() + " " + msg);
#endif
if (r.kind == tracker_request::announce_request)
{
announce_entry* ae = find_tracker(r);
if (ae)
{
ae->failed(retry_interval);
int tracker_index = ae - &m_trackers[0];
deprioritize_tracker(tracker_index);
}
if (m_ses.m_alerts.should_post<tracker_error_alert>())
{
m_ses.m_alerts.post_alert(tracker_error_alert(get_handle()
, ae?ae->fails:0, response_code, r.url, ec, msg));
}
}
else if (r.kind == tracker_request::scrape_request)
{
if (m_ses.m_alerts.should_post<scrape_failed_alert>())
{
m_ses.m_alerts.post_alert(scrape_failed_alert(get_handle(), r.url, ec));
}
}
update_tracker_timer();
}
#if defined TORRENT_VERBOSE_LOGGING || defined TORRENT_LOGGING || defined TORRENT_ERROR_LOGGING
void torrent::debug_log(const std::string& line)
{
(*m_ses.m_logger) << time_now_string() << " " << line << "\n";
}
#endif
}
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